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Ground Loop Design: Residential Edition

1. CHAPTER 5 The Horizontal Design Module Typical Operation Although each user will have his or her own unique style the typical operation of the Horizontal Design module would include the following steps 1 Enter Loads and select pumps in the Zone Manager module 2 Forma link between the loads module and the design module 3 Modify step by step the input parameters listed in each panel 4 Perform initial calculation 5 Modify various parameters and recalculate to determine the effects of the modifications 6 Establish an optimal system 7 Save and or print the project and associated zone file Entering Data into the Tabbed Panels Ground Loop Design s innovative tabbed panel system provides for easy organization of and direct access to the relatively large number of design parameters associated with a particular project This section describes the Information Extra kW Configuration Piping Soil Fluid and Results panels The Information and Extra kW panels are identical to those included in the Borehole Design module described in Chapter 4 so the reader is referred there for detailed information See Chapter 3 for a discussion of Loads entry Configuration Information pertaining to the trench configuration is in the Configuration panel This includes the trench layout and the pipe configuration in the trenches The input screen is shown in figure 5 1 Note that this configuration panel can be used for both trench and pit s
2. Undisturbed Ground Temperature Ground Temperature 56 0 F Soil Thermal Properties Soil Type Heavy Soil Darnp y Modeling Time Period 2 Prediction Time 10 0 years Fig 4 6 Soil Panel Contents The undisturbed ground temperature refers to the temperature of the soil below the surface layer where there is no longer a seasonal swing This value may be determined from regional data or by recording the actual stabilized temperature of water circulated through pipe in a test bore 44 CHAPTER 4 The Borehole Design Module The soil thermal properties thermal conductivity and thermal diffusivity are a little harder to define and care must be taken to select the correct soil type In the residential version of Ground Loop Design users can select the soil type that best matches the target installation soil environment The thermal conductivity in particular has a large effect on the calculated bore length and therefore soil type should be determined with care The following chart lists the conductivity and diffusivity values associated with each soil type option Soil Type Conductivity Diffusivity Btu h ft F ft day Light Soil Dry 0 20 0 26 Light Soil Damp 0 50 0 48 Heavy Soil Dry 0 50 0 48 Heavy Soil Damp 0 75 0 60 Heavy Soil Saturated 1 40 0 84 Solid Masonry 0 75 0 60 Dense Concrete 1 00 0 79 Average Rock 1 40 0 96 Dense Rock 2 00 1 20 Modeling
3. If the dongle is not attached to your computer GLD will function as a trial version which is fully functional except for a few design parameters that are locked at certain values When you insert the dongle into a free USB port on your computer for the first time your computer most likely will recognize the dongle and after a few seconds the dongle light will turn on When it turns on your license will activate However if your computer indicates that the dongle is new hardware you have two options for installing the dongle driver How to Install the Dongle Driver Windows Vista XP and Windows 2000 users with internet access If your computer has access to the internet your computer can automatically install the drivers Follow along with the Windows new hardware wizard to install the drivers The process takes a few minutes When the installation is complete the dongle light will turn on All other users Via Windows Explorer navigate to Main Drive Program Files Gaia Geothermal Ground Loop Design Residential Extras In the Extras folder you will find a HASPUserSetup exe program Run the program to install the dongle driver When the installation is complete the dongle light will turn on After Dongle Installation is Complete Now that the dongle is installed you can access the full functionality of the GLD version that you purchased If you remove the dongle the program will revert to demo mode If you
4. and vendors anywhere in the world is efficient and easy System Requirements for Running Ground Loop Design This section lists the hardware and software requirements for running Ground Loop Design Hardware Requirements A full installation has the following minimum hardware requirements e 256 MB Ram e 70 MB hard disk space 140 MB recommended Software Requirements Ground Loop Design has the following software requirements e System running under Windows e Netscape Navigator or Internet Explorer Operating System Requirements Ground Loop Design will operate under Windows 9X ME NT 2000 XP VISTA Internet Browser Requirements An Internet browser is required only for viewing the data reference files and not for general program operation To access the data reference files at least one of the following browsers is necessary e Netscape Communicator Version 5 1 or later A PREFACE e Internet Explorer Version 5 1 or later Installation Procedure If you have problems installing Ground Loop Design please visit the support page at http www gaiageo com or contact your distributor Note that you can also download Ground Loop Design from the internet at http www gaiageo com The downloadable version always will be the most recent release Initial Installation For CD versions of GLD installation should start automatically If not the software may be installed by clicking on the Setup exe file include
5. Design Pumps database also can include corrections to the capacity or power that result from variations in the load side inlet temperature or flow rate They are entered as correction factors across the desired temperature or flow range The software again uses the polynomial fitting to model these correction factors In these cases a four coefficient model is used to better model the types of variations that may occur 20 CHAPTER 3 Loads and Zones CHAPTER 3 The Zone Loads Module All of the calculations performed in Ground Loop Design fundamentally are based on loads provided by the designer This chapter describes the Ground Loop Design loads system and how to enter the loads into the zone loads module Additionally it explains the pump matching capabilities and operation both in automatic and in manual modes At the end of the chapter there is an explanation of how to import external loads files as well as a brief review of the program s loads input methodology Zone Files Zone loads files are stored as zon files in the Ground Loop Design Residential zones directory They have a general format that can be read into the loads module and they can be used simultaneously in different design modules However if this is done it may be wise to save any changes under different filenames Loads files are entirely independent of project design files This means that an entire installation loading design can be entered mat
6. Pipe 20 Methanol Table 5 Head Loss in SDR 11 and 17 HDPE Pipe Pure Water Some of these charts could have also been placed with the Pipe Properties tables but because they vary primarily with solution type they were placed here In an ideal world the Fluid Properties tables would include all of the graphs charts and tables for all of the parameters of all possible antifreeze combinations However because these variations are difficult to predict for specific projects only partial information has been included For the most accurate designs designers are encouraged to seek out their own favorite antifreeze combinations and determine the specific heat density and minimum required flow rate for non laminar flow Soil Properties Soil properties refer to any data related to the soil The three reference files are listed below 83 CHAPTER 8 Tables and Reference Files Table 1 Thermal Conductivity and Diffusivity of Sand and Clay Soils Table 2 Thermal Properties of Rocks at 77 F Table 3 Earth Temperatures Soil Swing and Phase Constants for U S and Canadian Cities The first two Soil Properties tables included with Ground Loop Design provide various soil parameters including ranges for thermal conductivity k and thermal diffusivity a for various types of soils These tables should not be considered accurate for a given location however they should provide the designer with a realistic range within which thei
7. Research Project RP 366 1985 Paul N The Effect of Grout Thermal Conductivity on Vertical Geothermal Heat Exchanger Design and Performance M S Thesis South Dakota State University 1996 17 CHAPTER 2 Adding Editing Heat Pumps CHAPTER 2 Heat Pumps Ground Loop Design has hundreds of heat pumps from a number of manufacturers loaded into its Heat Pump Database Although the Heat Pump Database is not modifiable in the residential version of Ground Loop Design it is important to understand how the system models heat pump data This chapter describes the theory of the module Heat Pump Model Description For convenience the Loads modules in Ground Loop Design predict how heat pump characteristics will vary with changes in the input design parameters If the designer changes the inlet source or load temperatures or the system flow rate the capacity and power data of the units may also change The easiest and most accurate way of realizing these changes is to 18 CHAPTER 2 Adding Editing Heat Pumps employ an internal model and database which the software uses to update the pump data automatically Using Ground Loop Design the designer can concentrate on the effects of variations without worrying about how the individual pumps in various zones will react to such changes The heat pump model and database employed in Ground Loop Design reproduces the complete operational data of any particular unit when supplied with a few
8. a link in the list of available tables By clicking on the link the CaCl2 density image CaCl2Density jpg will appear and can be used as a convenient internal reference Taking Care with Updates Updated versions of Ground Loop Design may have new reference files and new versions of FluidTables html SoilTables html or PipeTables html If this is the case then any custom changes to these files made by the user may be overwritten during a new installation Although the linked files will remain the user is advised to make backup files of all customized reference files before new Ground Loop Design installations or updates 87 CHAPTER 8 Tables and Reference Files Concluding Remarks The reference files in Ground Loop Design are added entirely for the user s convenience Designers should find the customizable geothermal Design Studio an ideal and familiar environment in which they can conduct their work with the highest levels of efficiency and confidence 88
9. calculations but the designer must first have a grasp of all of the individual inputs required and the relationships among them Finally the surface water designing process actually involves an additional stage of optimization that is not included with the Borehole Design module The Surface Water module includes a piping calculation component to assist the designer in selecting the best pipe sizes and circuit lengths 66 CHAPTER 6 The Surface Water Design Module Entering Data into the Tabbed Panels Ground Loop Design s innovative tabbed panel system provides for easy organization of and direct access to the relatively large number of design parameters associated with a particular project This section describes the Surface Water Piping Soil Fluid and Calculate panels The Information and Extra kW panels are identical to those included in the Borehole Design module described in Chapter 4 so the reader is referred there for detailed information See Chapter 3 for a discussion of Loads entry Surface Water Use the Surface Water panel to enter data related to the body of water being used as the heat transfer medium Figure 6 1 shows the associated input screen Surface Water Design Project 1 ES Results Fluid Soil Piping Surface Water Extra kW Information Surface Water Temperatures at Average Circuit Pipe Depth Summer 460 F Winter 39 2 E Details Reference Only Surface Water Type Pond Surf
10. capacity This is because it is assumed that all units will not be running at full load simultaneously even in the peak load condition HE Borehole Design Project 41 Results Fluid soil U Tube Pattern Extra kw Information Design Heat Pump Inlet Fluid Temperatures Cooling 80 0 F Heating 36 0 F Design System Flow Rate Flow Rate 3 0 gpmiton Solution Properties Fluid Type Ethylene Glycol Freezing Point 20 F 14 6 by Weight Check Fluid Tables Fig 4 7 Fluid Panel Contents 46 CHAPTER 4 The Borehole Design Module Optimized systems generally operate in the range from 2 5 to 4 0 gpm ton while the ideal system flow rate is somewhere around 3 0 gpm ton Again if the flow rate is changed the selected heat pumps are updated in the loads modules Solution Properties Solution properties are also included in the Fluid panel A reference label is included so that the designer knows the percentage of antifreeze and antifreeze type however this reference label is not currently linked to the other input parameters The user first selects the fluid type and then selects the desired freezing temperature Ground Loop Design automatically incorporates the specific heat and density for the fluid selection into the calculations See Fluid Properties table under the Table dropdown menu for the specific heat and density values for each fluid selection The specific heat and density values o
11. if other modules with the same name are already open As many files can be opened as the system s memory permits New Projects New projects may be opened at any time from the Design Studio by choosing New Horizontal from either the Design Studio File menu or the toolbar New projects open with standard parameter values that must be edited for new projects In new projects no loads files zon are loaded The user must create a new loads file or open an existing loads file into one of the loads modules Links may be established using the Studio Link system described in Chapter 3 t Existing Projects Existing projects may be opened at any time from the Design Studio by choosing Open from the Design Studio File menu or toolbar The file automatically opens into a new Horizontal Design Project module If a loads file zon is associated with the loaded project the loads file automatically will be loaded into the appropriate loads module and opened along with the project file However if the associated loads file cannot be found the user will be notified and the automatic file loading will not occur Saving Projects Projects may be saved at any time using Save or Save As from the Design Studio File menu or by clicking the save button on the toolbar When the user closes the program or module the program automatically asks the user if he or she wants to save the project and associated loads files 51
12. line source theory could be used to estimate the change in temperature of a buried pipe in which heat is being absorbed or rejected Ingersoll and Plass 1948 In a ground coupling system an apparent thermal resistance between the circulating fluid and the undisturbed ground dominates the overall resistance In 1985 in the ASHRAE Design Data Manual for Ground Coupled Heat Pumps Parker et al outlined a method by which this field resistance or soil resistance could be estimated and applied to determine piping and trench length requirements for a buried pipe system In the case of horizontal pipe systems located near the ground surface the mathematics necessitate the inclusion of mirror image pipes into the calculations These mirror image pipes are located the same distance above the surface as the buried pipes are below it In a multiple pipe system the soil temperature in the vicinity of any single pipe is determined by both the undisturbed earth temperature and by the thermal interference from other pipes in the same and in adjacent trenches Parker Bose and McQuiston 1985 The current Horizontal Module effectively employs a combination of the cylindrical model of Carslaw and Jaeger and the multiple pipe methodology of Parker et al Additionally as in the Borehole Module the equations also include modifications suggested by Kavanaugh and Deerman that adjust the methods of Ingersoll to account for physical arran
13. need to know further details about the design Loads List The Loads List lists only the loads associated with each zone It provides the design day loads at the different periods during the day in both heating and cooling modes For the Borehole Design module the Loads report includes the annual hours and weekly occupation information Names List The Names List is just a list of the full reference names of the different zones combined with the zone number pump name and number of pumps required for the zone It makes a convenient compact link between zone name and number and is especially useful when the project consists of many separate zones Concluding Remarks There is no data in Ground Loop Design that is not expressible in a printed form The designer can organize and share information both during the developmental stages of a project and after the design is complete 80 CHAPTER 8 Tables and Reference Files CHAPTER 8 Tables and Reference Files This chapter covers the tables and reference files of Ground Loop Design It starts with a description of the included files and then explains how the user may add customized files to the existing set Overview Ground Loop Design employs a technologically sophisticated system that allows the user to customize the reference files as much as he or she desires The reference files included with Ground Loop Design are minimal consisting of a few tables and graphs that shoul
14. of authorized licenses Customer has purchased Customer agrees to use reasonable efforts to protect the Software from any unauthorized use modification reproduction distribution and publication Customer may not transfer any of the rights granted to Customer hereunder unless Customer receives prior written authorization from Gaia and only if Customer transfers all of Customer s rights granted hereunder without retaining any of the Software or any copies thereof or any rights thereto Except as otherwise expressly provided under this End User Agreement Customer shall have no right and Customer specifically agrees not to i make error corrections to or otherwise modify or adapt the Software nor create derivative works based upon the Software or to permit third parties to do the same or ii copy in whole or in part decompile translate reverse engineer disassemble or otherwise reduce the Software to human readable form Upgrades and Additional Copies For purposes of this End User Agreement Software shall also include and the terms and conditions of this End User Agreement shall apply to any upgrades updates bug fixes or modified versions collectively Upgrades or backup copies of the Software licensed or provided to Customer by Gaia or an authorized distributor for which Customer has paid the applicable license fees and holds the corresponding software keys Notwithstanding the foregoing Customer acknowledges and agre
15. possible to access the latest web resources and updates If these resources do not answer your question please contact your vendor for support References Carslaw H S and Jaeger J C Conduction of Heat in Solids Oxford Claremore Press 1947 Hughes P J and Shonder J A The Evaluation of a 4000 Home Geothermal Heat Pump Retrofit at Fort Polk Louisiana Final Report Oak Ridge National Laboratory TN ORNL CON 460 1998 Ingersoll L R and Plass H J Theory of the ground pipe heat source for the heat pump Heating Piping and Air Conditioning 20 7 July 1948 Ingersoll L R Zobel O J and Ingersoll A C Heat conduction with engineering geological and other applications New York McGraw Hill 1954 Jones F R Closed Loop Geothermal Systems Slinky Installation Guide Rural Electric Research National Rural Electric Cooperative Association Oklahoma State University 16 CHAPTER 1 Ground Loop Design Overview International Ground Source Heat Pump Association and Electric Power Research Institute 1995 Kavanaugh S P and J D Deerman Simulation of vertical U tube ground coupled heat pump system ASHRAE Transactions Volume 97 pages 287 295 1991 Kavanaugh S P and Rafferty K Ground Source Heat Pumps Design of Geothermal Systems for Commercial and Institutional Buildings ASHRAE 1997 Parker J D Bose J E and McQuiston F C ASHRAE Design Data Manual for Ground Coupled Heat Pumps ASHRAE
16. representative data points selected from across the range of interest Data for each pump has been entered into the model and database and grouped together under manufacturer and series headings Pump data are stored permanently in the pumps directory Many popular pumps from major manufacturers already are included with the program In both heating and cooling modes the minimum data required is the capacity and power variations with source inlet temperature To increase the modeling accuracy these same variations have to be included at a second flow rate Even more accurate results can be obtained if correction factors are provided for variations in the load inlet temperature and flow rate The level of accuracy depends on the amount of data available from the manufacturer Note that Ground Loop Design s heat pump module allows for both water to air and water to water pumps Theoretical Basis Capacity and Power Heat pump capacities and power requirements vary smoothly but significantly for differing source inlet temperatures Three points taken along both the capacity vs temperature and power vs temperature curves are fit to a polynomial equation to model these variations The resulting calculated coefficients are then used to generate capacity or power values for any given source inlet temperature The basic polynomial equation used for fitting has the form y a bx cx where a b and c are the three coefficients calculate
17. results such as the required trench and pipe lengths the inlet and outlet temperatures the coefficient of performance COP etc based on the input data The input information is organized into seven panels as shown in figure 1 2 Results Fluid Soi Piping Configuration Extra kW Information Fig 1 2 Horizontal Design Panel List 11 CHAPTER 1 Ground Loop Design Overview Using these seven panels Results Fluid Soil Piping Configuration Extra kW and Information the user enters the project specific information A more complete description about how to enter data and perform calculations in the Horizontal Design module is provided in Chapter 5 Theoretical Basis The horizontal trench length equations used in the Horizontal Design module are based upon the Carslaw and Jaeger solution for heat transfer from cylinders buried in the earth as described in the single vertical case above Again this method properly models shorter time periods of heat extraction or rejection where the simple line source model fails Since a number of pipes may be buried in close proximity this model must be modified to account for all mutual pipe interactions A major benefit derived from using this model besides its ability to accurately assess heat transfer is that both the horizontal and the vertical design modules can operate under the same loads formalism In 1948 Ingersoll and Plass demonstrated that the Kelvin
18. the associated results The zone and loads information is not included with the report and must be printed separately from the Loads panel The filename of the zon file associated with the project report is also listed on the report More information on reports can be found in Chapter 7 References Francis E Editor Refrigeration and Air Conditioning 3 Edition Air Conditioning and Refrigeration Institute p 186 Prentice Hall New Jersey 1997 62 CHAPTER 5 The Horizontal Design Module Incropera F and Dewitt D Introduction to Heat Transfer 2 Edition p 456 p 98 John Wiley and Sons New York 1990 Paul N The Effect of Grout Thermal Conductivity on Vertical Geothermal Heat Exchanger Design and Performance 63 CHAPTER 6 The Surface Water Design Module CHAPTER 6 The Surface Water Design Module This chapter describes the features and operation of the Surface Water Design module This module is for the design of systems that use bodies of water including ponds rivers lakes oceans etc It is one of the three design modules included with Ground Loop Design Overview As with the Borehole and Horizontal Design modules the calculations made in the Surface Water Design module involve the combination of a large number of input parameters Care must be taken to assure that proper values are verified before use Assuming that reasonable values are provided to the software the software will provide a reasona
19. 0 0 0 46 7 3 7 12 5 98 4 EVO30 1 26 0 18 0 15 0 0 0 30 0 2 1 14 3 87 5 EV048 2 20 0 36 0 90 0 0 0 93 5 7 5 12 5 96 6 GEHA 036 2 62 0 56 0 0 0 0 0 70 4 5 8 12 0 88 l Evo4s 2 0 0 0 8 0 3 6 2 LES 2 EVO48 2 A820 6820 660 5 0 95 9 62 425 219 3 EVO48 L Agos 20 0 10 0 1220 476 LE 45 080 4 EVO30 1 2405 10860 10 0 Bose 2279 221 2 2 8 87 5 EVO48 2 53 0 18 0 21 0 23 0 95 3 6 2 4 5 56 6 GEHA 036 Z 42 0 10 0 15 0 18 0 66 0 5 3 3 7 64 COOLING HEATING Total Unit Capacity MBtu Hr 469 6 464 7 Peak Load MBtu Hr 342 0 243 0 Peak Demand kW 27 3 17 3 Heat Pump EER COP 12 5 4 2 Peak Load Period Noon 4 p m 8 a m Noon Flow Rate 3 0 apmiton Unit Inlet F 85 0 50 0 jenna Fig 3 3 Zone Manager Summary View Entering Loads Loads can be entered directly in the individual zone data windows back in the Main View of the Loads tabbed panel A sample entry is shown in figure 3 4 Maximum Loads The peak maximum hourly load for the design day or the day of heaviest usage in the year for both cooling heat gains and heating heat losses modes of operation can be input In figure 3 4 below peak hourly cooling and heating loads are 25 kBtu hr and 36 kBtu hr respectively 25 CHAPTER 3 Loads and Zones Loads Information Maximum Loads Cooling Heating kBtujHr kBtu Hr 25 0 36 0 Annual Running Time 0 100 2 Fig 3 4 Sample Loads Input Data Annual Running Time 0 100 The percenta
20. 80 E E T A E ee 80 NCAA A E E E 80 Concluding Rema ES a e a e a a a a a a e inta kalia 80 Chapter 8 Tab les and Data Reference Files ccssceseeeeeeeeeeesO2 OVERVIEWS oscctee A Aiea ad Hpk Shiels anata wee 82 Tables Included with Ground Loop Design cececeeceee eee ee eee ene eens ene eaeneees 82 A AA te ay oe a ETETE R oa 83 Soil Properties ur Nee oda ehh Sa ee ae SR 83 Pipe Properties vse cis di aca 83 CONVE aiii each 84 Adding Customized Reference Files 0 cccececeeceecee eee e eect eset eee eaeaeeaenaenens 85 Original Model sisi a hs Ghee ge ASR da EO 85 HIME Pilesy cd cacigaoas recta vers podas id ops weet 85 Editing Existing Files 00 ccccccecceeeceeceeene eee eeeeeeeeneeeeeaeeaeas 86 Making A Tabla ies 86 Adding a Picture Graph or FIgure oooooocooconcnconcnnononcnncnnonnnnos 87 Taking Care with Update iii a iia 87 Concluding Remarks acia id nas bes 88 PREFACE PREFACE Before You Begin This chapter describes the typical uses and users of the software It also describes the installation procedure and hardware and software requirements for the Ground Loop Design program Additionally the chapter introduces the licensing system Introduction Typical Uses and Users Ground Loop Design Residential Version 5 1 is intended as a Design Studio for HVAC designers working in the area of geothermal applications It is primarily designed for use
21. ATA OR FOR SPECIAL INDIRECT CONSEQUENTIAL INCIDENTAL OR PUNITIVE DAMAGES HOWEVER CAUSED AND REGARDLESS OF THE THEORY OF LIABILITY ARISING OUT OF THE USE OF OR INABILITY TO USE THE SOFTWARE EVEN IF GAIA OR ITS SUPPLIERS HAVE BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES IN NO EVENT SHALL GAIA S OR ITS SUPPLIERS TOTAL LIABILITY TO CUSTOMER WHETHER IN CONTRACT TORT INCLUDING NEGLIGENCE OR OTHERWISE EXCEED THE PRICE PAID BY CUSTOMER THE FOREGOING LIMITATIONS SHALL APPLY EVEN IF THE ABOVE STATED WARRANTY FAILS OF ITS ESSENTIAL PURPOSE BECAUSE SOME STATES OR JURISDICTIONS DO NOT ALLOW LIMITATION OR EXCLUSION OF CONSEQUENTIAL OR INCIDENTAL DAMAGES THE ABOVE LIMITATION MAY NOT APPLY TO CUSTOMER Term and Termination This End User Agreement is effective until terminated Customer s license rights under this End User Agreement will terminate immediately without notice from Gaia if Customer fails to comply with any provision of this End User Agreement Upon termination Customer must destroy all copies of Software and the corresponding keys in its possession or control Compliance With Law Each party agrees to comply with all applicable laws rules and regulations in connection with its activities under this End User Agreement Without limiting the foregoing Customer acknowledges and agrees that the Software including technical data is subject to United States export control laws including the United States Export Administration Act
22. Circuit Head Loss per 100 feet This is the head loss for the particular style of pipe These values are not entered automatically Instead they come from designer s charts A chart in English units is included with Ground Loop Design in the Pipe Tables section The designer must be aware that this value changes with pipe size temperature and flow rate Extra Equivalent Length per Circuit This is an average pipe length value included per circuit to take into account all fittings elbows tees etc It is only necessary for the head loss calculations 70 CHAPTER 6 The Surface Water Design Module ES Surface Water Design Project 1 Results Fluid Soil Piping Surface Water Extra kw Information Header Primary Number of Lines 1 Pipe Size E 12 in 37 5 mm x Header Length In Water 50 0 ft In Soil 50 0 ft Head Loss per 100 feet Cooling 20 ft hd Heating 1 0 ft hd Fig 6 3 Piping Header Panel Contents Header Parameters The Ground Loop Design Surface Water module assumes that a standard supply and return line design will consist of mains followed by a manifold that splits the mains into the headers Headers are generally the first pipes to enter the ground or water In the Piping panel the model employed allows for multiple headers If further branching is required the head loss calculations will need to be calculated and added separately Their effect on the calculated piping l
23. Ground Loop Design Residential Edition Geothermal Design Studio Residential GLD Software Gaia Geothermal User s Manual English Ground Loop Design Residential Version 5 1 for Windows Gala pc Geothermal www gaiageo com Copyright Notice Ground Loop Design Residential 5 1 User Manual 2008 Celsia LLC All Rights Reserved This guide as well as the software described in it is furnished for information purposes only to licensed users of the Ground Loop Design software product and is furnished on an AS IS basis without any warranties whatsoever express or implied This may be used or copied only in accordance with the terms of the included End User License Agreement The information in this manual is subject to change without notice and should not be construed as a commitment by Gaia Geothermal Gaia Geothermal assumes no responsibility or liability for errors or inaccuracies that may occur in this book Except as permitted by such license no part of this publication may be reproduced stored in a retrieval system or transmitted in any means electronic mechanical recording or otherwise without the prior written consent of Gaia Geothermal Other brand and product names are trademarks or registered trademarks of the respective holders Microsoft Excel Windows Windows 95 Windows 98 Windows NT Windows Explorer Windows ME Windows XP and Windows 2000 are registered trademarks
24. L Original Model The original model included with Ground Loop Design consists of these files English Metric FluidTables html FluidTablesMetric html FluidTable1 html FluidTable1Metric html FluidTable2 html FluidTable2Metric html FluidTable3 html FluidTable4 html FluidTable5 html SoilTables html SoilTablesMetric html SoilTable1 html SoilTable1Metric html SoilTable2 html SoilTable2Metric html SoilTable3 html SoilTable3Metric html PipeTables html PipeTablesMetric html PipeTable1 html PipeTable1Metric html PipeTable2 html PipeTable2Metric html PipeTable3 html PipeTable3Metric html To add a new file the FluidTables html the SoilTables html or the PipeTables html must be edited The user must create a link in one of the three aforementioned html files to the new file which contains the table graph or image that the user would like to have available in Ground Loop Design Note Ground Loop Design requires the FluidTables html SoilTables html and PipeTables html files and their metric counterparts FluidTablesMetric html SoilTablesMetric html and PipeTablesMetric html as the initial files when opening the associated tables They can be edited but if they are deleted the associated tables cannot be opened at all HTML Files HTML refers to Hypertext Mark up Language It is the language used on web pages and commonly used in software to quickly provide linked information to users HTML files can be created with an HTML ed
25. Theoretical Basis cid dida 10 Horizontal Design Module 00 cececceceee eee eeeee ences ene eeeaeneeeeaeneees 11 Descriptions se52ce yeas NS ceeds eed ee ba ce hed 11 Theoretical Basis 22c2 9 iio ries 12 Surface Water Design Modulle cccccsscesecseeseeeseeseceecesecesceeceeeeeseeseeeaeeseeeneennee es 13 Description 6 2235204 ii daa pio 13 Theoretical Basicos 14 Additional Modular tala REPOSO dass 15 Project Reports uc iaa 15 ZoOne Loads Repo iia ed 15 Data Reference Elli dlo Program Help and Up tu a 16 References masai seadiaieicececasGuiashiGeetecmaatiaiataset ENS 16 Chapter 2 Adding Editing Heat PUMPS oooccccccccccccccncncncninnnanin anna ra 18 Heat Pump Modelo de 18 NS A eek od E Ned ete bs DSS oR 18 Theoretical Basis Yoana tates 19 Capacity and Power AENEA EEE AA E 19 Plow Rat s nccceisnetinieti adieiosnyoet EE E Ea 20 Load Side Corrections ccceceeeeeseneeeneeeeneeenene eee ee serena en ree 20 CONTENTS Chapter 3 The Zone Loads Module ooooccicnncicococccconcccnanonanananan naa 21 Zone Pl dd ta is 21 The Zone Manager Loads Module ccccccececeecenee ene eneeeeee ene eneeeeeeeneeeeneea 22 Managing Zones in the Loads Tabbed Panel ccceceeeeeeeeeneee ee en tees 23 New and Copy es Crache acs E 24 Removerand Clear dandole aaa E eNA Da 24 Renumber aee Ene ae eden totes in e er adaa aeaea da 24 Summary View Toggle Button ccc cece eee e e
26. ace Area 8000 ft 2 Circuit Pipe Depth 12 0 ft Fig 6 1 Surface Water Panel Contents 67 CHAPTER 6 The Surface Water Design Module Surface Water Temperatures at Average Circuit Pipe Depth These are the temperatures in the body of water at the depth where the majority of the pipe will reside The Circuit Pipe refers to the main heat exchanger portion of the pipe and does not include the header pipe leading from the surface Temperatures in bodies of water naturally change from summer to winter Both temperatures at the circuit pipe depth should be included in this section Details Reference Only The surface water details are not used in any calculations They are included for the designer s reference Several different types of water bodies are included but the designer can type anything in the selection box Piping The Piping panel contains all the information related to the circuit piping and the piping selected for the primary header s The heat exchanger circuits actually dominate the heat transfer but if the supply and return lines are long or exposed to different design conditions care must be taken with the header heat transfer The input screen for the piping circuit panel is shown in figure 6 2 Figure 6 3 is the input screen for the piping header panel 68 CHAPTER 6 The Surface Water Design Module rae Surface Water Design Project 1 Results Fluid Soil Piping l Surface water Extra
27. across and rows down boxes Separation between Vertical Bores This value is the center to center distance between adjacent bores For optimal use of space the current calculations allow only one spacing distance between vertical bores in either direction 41 CHAPTER 4 The Borehole Design Module EJ Borehole Design Project 1 Results Fluid Soil U Tube Pattern extra kW Information Fixed Length Mode l On off Yertical Grid Arrangement Borehole Number Rows Across Rows Down Borehole Separation Fig 4 4 Pattern Panel Contents U Tube The U Tube panel contains information related to the pipe and bore The main purpose of the panel is to obtain a value for the borehole thermal resistance which is calculated according to the method of Paul and Remund Paul 1996 The panel contents are shown in figure 4 5 42 CHAPTER 4 The Borehole Design Module Ei Borehole Design Project 41 Results Fluid Soil U Tube Pattern Extra kW Information Pipe Parameters Pipe Size 1in 25mm Pipe Type SDR11 v Flow Type Turbulent Borehole Diameter Borehole Diameter 4 00 in Backfill Grout Information Thermal Conductivity 0 85 Btujih ft F Fig 4 5 U Tube Panel Contents Pipe Parameters The pipe parameters are entered in the Pipe Parameters section They include the pipe size pipe type and pipe flow Ground Loop Design calculates the convective resistance using
28. al effects that determine the necessary design requirements Such systems generally require more advanced engineering capacity Ground Loop Design Premier Version 5 0 provides significantly enhanced functionality for such systems Contact your distributor for more information 22 CHAPTER 3 Loads and Zones 4 Zone Manager Heat Pumps Loads DOG a Bl su amp g P Untitled zon Zone 1 Loads Panel gt Reference Label Loads Information Maximum Loads Cooling Heating kBtu Hr kBtufHr 0 0 0 0 Annual Running Time 0 100 El gt Heat Pump Specifications at Design ia and Flow Rate Pump Name JW Custom Pump con Cooling Heating Auto Select Capacity kBtu Hr Power kW EER COP Flow Rate gpm Partial Load Factor Select Details Flow Rate 3 0 opmiton Unit Inlet F Fig 3 1 Zone Manager Loads Module Main View The Zone Manager loads module can be opened either from the Loads Menu or by clicking the Zone Manager toolbar button An example of the module opened to the Loads tabbed panel is shown in figure 3 1 The Heat Pumps tabbed panel will be discussed shortly In the Main View Zones in Ground Loop Design are organized in a list on the left side of the Loads tabbed panel Each zone panel contains information relating to the working zone including a zone name the loading information and the information about any heat pumps selected for that zone Selecting a different zone name i
29. ample input screen is shown in figure 5 5 Design Heat Pump Inlet Fluid Temperatures The heat pump inlet fluid temperatures are included in the Fluid panel The designer can input the desired inlet source temperatures for both heating and cooling here When changes are made to these values the heat pumps in all zones are updated automatically Since the new calculated equipment capacities can lead to changes in selected equipment the designer must be aware of the changes Customized pump values must be adjusted manually Design System Flow Rate The system flow rate per installed ton is included on the Fluid panel This is the system flow rate per ton of peak load not installed capacity This is because it is assumed that all units will not be running at full load simultaneously even in the peak load condition Optimized systems generally operate in the range from 2 5 to 4 0 gpm ton while the ideal system flow rate is somewhere around 3 0 gpm ton Again if the flow rate is changed the selected heat pumps are updated in the loads modules 59 gt gt CHAPTER 5 The Horizontal Design Module as Horizontal Design Project 2 Results Fluid Soil Piping Configuration Extra kw Information Design Heat Pump Inlet Fluid Temperatures Cooling 85 0 F Heating 45 0 F Design System Flow Rate Flow Rate 3 0 gpmiton Solution Properties Fluid Type Propylene Glycol y Freezing Point 30 F 5 9 by Wei
30. and its associated regulations and may be subject to export or import regulations in other countries Customer agrees to comply strictly with all such regulations and acknowledges that Customer has the responsibility to obtain licenses to export re export or import the Software Restricted Rights The Software shall be classified as commercial computer software as defined in the applicable provisions of the Federal Acquisition Regulation the FAR and supplements thereto including the Department of Defense DoD FAR Supplement the DFARS The parties acknowledge that the Software was developed entirely at private expense and that no part of the Software was first produced in the performance of a Government contract If the Software is supplied for use by DoD the Software is delivered subject to the terms of this End User Agreement and either i in accordance with DFARS 227 702 1 a and 227 7202 3 a or 11 with restricted rights in accordance with DFARS 252 227 7013 c 1 i OCT 1988 as applicable If the Software is supplied for use by a Federal agency other than DoD the Software is restricted computer software delivered subject to the terms of this End User Agreement and i FAR 12 212 a ii FAR 52 227 19 or iii FAR 52 227 14 ALT IID as applicable General This End User Agreement will bind and inure to the benefit of each party s successors and assigns provided that Customer may not assign or transfer this End Use
31. ations in inlet source or load temperatures or system flow rate will not affect a customized pump s data Automatic Heat Pump Selection Options for the Entire Zone Set Two controls are included with Ground Loop Design that allow for an automatic selection of pumps throughout the entire set of zones This feature is useful when the pump set needs to be compared or changed or when modifications are required throughout the existing set These controls are necessary so that large sets of pumps can be changed or updated without having to step through each individual zone hd Auto Select All Pumps The Auto Select All Pumps control performs the same function as the Auto Select button in the pump selection section of the zone data window except it performs the selection sequentially through all of the zones It uses the active heat pump series selected on the Heat Pumps tabbed panel Note Auto Select All Pumps will overwrite all currently selected pumps including custom pumps Sl Update Reselect Current Pumps The Update Reselect Current Pumps control reselects the pumps in all zones after determining the current series used in each particular zone For example if most of the pumps belonged to the same water to air series but one was a water to water pump this control would determine the difference and update the pumps accordingly Note Custom pumps are not affected when the Update Reselect Current Pumps control is activated Work
32. ble result General Features The Surface Water Design module in Ground Loop Design also includes a set of panels grouped by subject through which the designer can enter and edit the input variables in a straightforward and efficient manner For example parameters related to the body of water are listed on the Surface Water panel while piping choices are listed on the Piping panel Everything related to a project is presented simultaneously and easily is accessible throughout the design process 64 CHAPTER 6 The Surface Water Design Module The Surface Water Design module includes several additional features Metric and English unit conversion Printed reports of all input and calculated data Convenient buttons to bring up tables and calculators A Calculate button used to refresh the calculations A system to monitor header piping head losses Opening Projects There are two ways to open Surface Water Design projects One is by using the New Surface Water command from the Design Studio File menu and the other is by opening an existing Surface Water Design project gld file Files cannot be opened if other modules with the same name are already open As many files can be opened as the system s memory permits New Projects New projects may be opened at any time from the Design Studio by choosing New Surface Water from the Design Studio File menu or the toolbar New projects open with standard parameter va
33. ched with pumps optimized and saved without ever opening a design module This is valuable for users who wish to keep the loads entry and pump selection completely separate from the studio s geothermal design modules Now users can work on designs and load 21 CHAPTER 3 Loads and Zones inputs at different times and can use the same loads files for various projects styles of project New zone files can be created by clicking the New button in any loads module or by clearing all of the current loads information with the Clear button followed by the New button The designer provides a filename when the zone file is saved Zone files can be opened and saved using the Open and Save buttons on the Loads panel The Zone Manager Loads Module Small residential systems may have a single zone and a single heat pump Somewhat larger residential systems may have a single zone and several heat pumps Even larger residential systems may have multiple zones and multiple heat pumps The Ground Loop Design zone manager loads module provides the designer with enough flexibility to accept loads data for a range of residential systems GLD Residential Version 5 1 can be used to design systems with peak loads of up to 300 kBtu hr Systems with larger peak loads often are characterized as commercial systems and generally require more advanced loads calculations to take into account both internal heat gains losses as well as long term therm
34. d This button allows the designer to choose any of the stored pumps As with the Auto Select button all of the associated fields are calculated automatically once the pump is selected When the Select button is pressed the selection panel appears as shown in figure 3 6 After a pump is chosen pressing Select Pump will place the pump in the zone and automatically calculate all of the associated parameters Cancel will return the user to the main display without changing any pumps Note Unlike with Auto Select a pump that is manually selected may or may not match the loads in the zone It is the responsibility of the designer to make sure the pumps match the zones mHeat Pump Specifications at Design Temperature and Flow Rate Florida Heat Pump WP Series Water to Water Pump Name WPO36 y Select Pump Cancel Number of Units 1 E Fig 3 6 Pump Selection Panel 28 CHAPTER 3 Loads and Zones Details Specific details about a given pump may be obtained by clicking the Details button Additionally the details panel is where the designer may vary the loads input temperatures or flows for that particular pump After the user presses the return button variations in the input load temperature will affect the pump parameters listed on the main pump selection area A sample details panel is shown in figure 3 7 Heat Pump Specifications at Design Temperature and Flow Rate Pump Manufacturer Florida Heat Pu
35. d aid in the selection of requested parameters All files are written in open HTML Hypertext Mark up Language files The designer can edit and add to them as he or she desires to create a customized reference library within the Design Studio environment As with the heat pump and loads models the reference files model is another customizable element of the geothermal Design Studio that the user has the option to control Tables Included with Ground Loop Design Several tables are included with Ground Loop Design They are separated into several broad categories from which most questions will arise These include 82 CHAPTER 8 Tables and Reference Files Fluid Properties Soil Properties Pipe Properties Conversions The first three sections present a menu screen with hyper links to various tables that have been included in the package The fourth section consists of a pair of metric to English units conversion tables that answer most common engineering conversion problems Below is a description of the included files Fluid Properties Fluid properties refer to any data related to the circulation fluid The five Fluid Properties tables in Ground Loop Design are the following Table 1 Densities and Specific Heats of Various Solutions Table 2 Minimum Required Flow Rate for Non laminar Flow Tables 3 5 included only in English Units Table 3 Head Loss in SDR 11 HDPE Pipe 20 Propylene Glycol Table 4 Head Loss in SDR 11 HDPE
36. d from the fitting routine For the capacity case y represents the capacity and x is the desired temperature For the power input determination y is the power and x again is the temperature 19 CHAPTER 2 Adding Editing Heat Pumps The software stores coefficients for each pump in the database and then uses the coefficients with the source inlet temperatures chosen by the designer to determine the unit capacity and power Flow Rate To model the effect of the source flow rate on the calculated capacity and power data from a second flow rate are used Generally speaking with different flow rates the shape of the capacity and power curves does not change significantly but is shifted up or down by a constant factor This factor is determined for each of the three temperature data points and averaged over those input to obtain the linear flow factor which is shown on the input screen Once the flow factor is determined the linear capacity or power change per flow unit may be calculated The program then calculates a new capacity or power at any specified flow rate using the initial values already known from the stored data Considering the size of the variations generally only a few percent this simple model is accurate enough for most pumps A completely accurate model of the flow rate variations for all possible pumps would require significantly more data entry Load Side Corrections The Ground Loop
37. d on the disk The program is set to install in the folder Main Drive Program Files Gaia Geothermal Ground Loop Design Residential If desired the user can specify a different location during the installation sequence Installation of Updated Versions or Re Installation If the user re installs or replaces the software with a more recent version the user either can uninstall the program or can just update a current version To completely remove a version go to the Windows Start Menu gt Settings gt Control Panel gt Add Remove Programs and choose to remove Ground Loop Design After removing the program please conduct the new installation as described above As long as the user does not manually delete folders existing work files pumps and zone files will not be affected Customized data reference files should be backed up before any user modified Ground Loop Design menu HTML documents are replaced The linked HTML documents themselves will not be overwritten Program Licensing This section describes the USB dongle and license transfer options available in Ground Loop Design Residential Version 5 1 PREFACE Software License Dongle Your GLD software license is stored on the USB dongle that came with your program This dongle enables you effortlessly to transfer GLD from one computer to another Please be careful not to misplace this dongle Lost dongles can not be replaced without the purchase of a new license
38. d results Zone and loads information can be printed separately from the Loads panel The filename of the zon file associated with the project report is also listed on the report More information on reports can be found in Chapter 7 76 CHAPTER 7 Reports CHAPTER 7 Reports This chapter covers the report creation and printing features of Ground Loop Design It includes both project and zone reports Overview Ground Loop Design includes reporting features These features have been added for professionals who need to keep records of their designs and communicate them to others There are nine different report styles included within the package and this chapter provides an explanation of as well as suggested uses for each type of report The Report Preview Window When a particular report is selected a report preview window opens to show a preview of the report Report preview windows have a zoom feature that allows adjustment of the magnification Additionally reports may be sent to a printer or exported as various file types including text and html Multiple reports may be opened simultaneously even if they originate from the same project Report preview windows do not react directly to metric English unit conversion Instead a report opens with the same units used by its parent design module If another system of units is required the user must first change the unit system of 77 er CHAPTER 7 Reports the desi
39. de easily accessible graphs or charts that may be required repeatedly through the course of a design Similar design plans can be compared directly or entirely different designs can be created and varied All of the information a designer needs exists in one convenient location within Ground Loop Design Besides opening and closing windows and taking care of file management the studio desktop menu and toolbar include control features which can be applied to more than one different type of project For example the English metric unit conversion tool can convert a single window without affecting the rest of the open windows Project reports can also be printed from the studio desktop Customization Ground Loop Design offers the user a great deal of freedom in how he or she enters and uses information Rather than conforming designs to the software this software package allows some modification and variation in its included features Some of the most common areas of customization in Ground Loop Design include the entry of loads and the selection of equipment For example different families of pumps can be used within a single project and even individual pumps not included in the pre defined pump sets can be employed as required Another area where customization is possible is in the data reference files which are based on HTML With a simple HTML editor the user can include any tables data pictures graphs charts or any other useful infor
40. e and then from the water to the circuit pipes Different heat transfer calculations are used for the header pipe buried in the soil and the header pipe submerged in the water Head Loss per 100 feet This is the head loss for the particular style of pipe These values are not entered automatically Instead they come from designer s charts A chart in English units is included with Ground Loop Design in the Pipe Tables section As mentioned above the designer must be aware that this value changes with pipe size temperature and flow rate Soil The Soil panel is included only for the heat transfer calculations associated with the portion of the header pipe in the soil The model uses the undisturbed ground temperature of the soil This temperature then is used to determine how much heat is transferred from the header pipe to the soil or vice versa Once the amount of heat transfer from or to the soil is known the circuit pipe length calculated from the surface water data can be modified to provide fluid with the desired inlet source temperature to the heat pumps 72 CHAPTER 6 The Surface Water Design Module The Soil panel input screen is shown in figure 6 6 E Surface Water Design Project 1 Results Fluid Soil Piping Surface Water Extra kW Information Undisturbed Ground Temperature Ground Temperature 62 1 F Fig 6 6 Soil Panel Contents Fluid The fluid panel is identical to the one desc
41. e calculation techniques suggested by Remund and Paul to account for pipe placement grout conductivity and borehole size Paul 1997 Additionally the software calculates the amount of energy absorbed by or withdrawn from the ground using the load information collected from the individual zones and their relationship to the equipment selected The calculations find the conditions for long term steady state operation of borehole fields based on the desired heat pump inlet temperatures In order to provide an optimum design and prevent system failure the combination of parameters must allow for proper extraction or dissipation of energy from or to the earth at the location of interest The most complete description of the calculations and input data can be found in Chapter 3 of the book Ground Source Heat Pumps Design of Geothermal Systems for Commercial and Institutional Buildings by S P Kavanaugh and K Rafferty 1997 In extensive tests this model consistently proved to be the most accurate when compared with calibrated data from actual installations Hughes and Shonder 1998 Horizontal Design Module Description The Horizontal Design module similar to the Borehole Design module allows the user to enter parameters necessary to describe a horizontal buried pipe and trench configuration Again the interface is arranged in panels corresponding to the type of input After the user enters all parameters the software calculates
42. eat pumps stored within Ground Loop Design s Heat Pump Database Therefore ideal and rapid sizing is possible The annual running time 0 100 also may be included for a buried heat exchanger This loading information can be simple or complex depending on the level of detail the designer desires To facilitate this model the zones can be viewed either independently or together on the summary panel Design Modules The Ground Loop Design Geothermal Design Studio consists of the following three design modules e The Borehole Design Module In fixed temperature mode this module calculates the lengths of bore required for a vertical borehole exchanger system In fixed length mode it models the inlet temperatures for a user defined borehole field length e The Horizontal Design Module This module determines the length of piping required for a horizontal slinky exchanger system in trench or pit configurations e The Surface Water Design Module This module determines the length of piping required when a closed loop of pipe inserted into a body of water acts as the heat exchange medium All three modules are linked to zone loads module using the Studio Link system Borehole Design Module Description The Borehole Design module allows the user to enter various parameters with respect to the desired vertical borehole system Input is arranged in panels corresponding to the type of input as shown in figure 1 1 Results F
43. ee ee ee eee eee een e nee 24 Entering Lords iia il 25 Maxi m Lo Sis ainia 25 Annual Running Time 0 100 oooooooccccccnconcononcnncnnoncnncnnonnos 26 Pump Matching and Selection ccc ccc eceeceee ee ecee eee eee eae ee ene eaenaeaes 27 AVO S elete oh a nor da dielslahithd deine neat adasled castle 28 Manual Selena sich dida aeee 28 A A th e ee ea ada daradatte dealers 29 O lai Adlets lalate eda e eiS 29 Custom Pump Customization cccceceececeec eee eeeee ee eaeeaees 29 Automatic Heat Pump Selection Options for the Entire Zone Set 30 Auto Select All Pumps 0 ccc cesec eee ee eee e nent ene eneee eaten ena enes 30 Update Reselect Current PUmpsS 0 ccceceeceeeee eee eneee eae eneees 30 Working Series Selection in the Heat Pumps Tabbed Panel 04 30 Choosing the Active Series cccccececeecee enc ene cess eeeneeaeenees 31 Inlet Load Temperatures 0 ccccceeseceec ee eec ene eeeneeneeeeneeaeens 31 Pump Continuous Update Feature 0 c cece ccc e cece nee e ne ene een e eae eeeneeaenaenaeaenaes 32 The Studio Link System 0 nicesi eein e ine oee nese eset E E E E eai 32 Making a Cink vincia EE EERE E EREE TE 32 UnlinM e arar E EREE EEE E REE E ESE AE Rp E 33 Studio Link Status Lights 0 00 00 cece cece ese c ee eeee ee eee e nent eect teense enaen a 33 Importing Loads Data From External Prog
44. ength which cannot be included will depend on their length All headers are assumed to have an identical pipe size and an approximately equivalent flow Ground Loop Design uses the header information so that the heat transfer losses or gains are taken into account The software then uses this corrected value iteratively to modify the length of the circuit loop piping so that the desired entering water temperature for the heat pumps is provided 71 CHAPTER 6 The Surface Water Design Module Additionally the program calculates the average head losses of the system when provided with the head losses per 100 ft for each type of pipe in the system These values vary with pipe size antifreeze and flow rate Several graphs are provided with the program to help determine these values for pure water and standard solutions but the designer is ultimately responsible for making sure the appropriate values are entered These head loss calculations also require the one way length of the header which is doubled within the program to account for both the supply and return lines Number of Lines This is the number of header lines in the system Pipe Size This is the size of the pipe used in the primary headers For pumping reasons the size of the primary header is generally larger than the circuit pipe sizes Header Length Average Branch Length This is the designer defined one way length of the pipe from the installation to the water lin
45. ength to a desired value is to change the trench number on the Configuration panel The associated pipe length both total and for a single trench directly follow the reported trench lengths The pipe lengths are a function of the selected configuration of pipe in the trench so the length of trench is always less than the length of pipe when anything other than a single pipe configuration is chosen The following subsection of the report lists the heat pump inlet and outlet temperatures of the circulating fluid The next subsection lists the total unit capacity the peak loads and demand of all the equipment and the calculated heat pump and system efficiencies The peak load is the maximum and is determined from whichever time period across all the zones has the highest load The peak demand includes all pumps and external energy requirements including those listed in the Extra kW panel Finally the system flow rate is listed in its own subsection The system flow rate is calculated from the peak load divided by 12 000 Btu ton and then multiplied by the flow rate in gpm ton chosen on the Fluid panel It represents the flow rate from the installation out to the buried pipe system Printing Reports A report of the active project can be printed at any time from the Design Studio using the toolbar print button or from the File menu gt Print The information printed includes all of the input parameters from the design module along with
46. er Temperatures at Average Circuit Pipe Depth 68 Details Reference ON Y o oooooooocooconconcnconcnnonrnonnonnnncnnannonnnns 68 PMA a NT aia 68 Circuit Parameter Soris aoei woe eevee ay eee nee ee 69 Circuit Pipe Si ZO irn 264 ben ona EE a 69 Number of Parallel Circuits 0 0 c ce ceeceec eens eneeeeeenes 69 Circuit SW Soak ese ee Gn wh et ee ect 70 Circuit Head Loss per 100 feet 00 ce cece eee eee ene eeenees 70 Extra Equivalent Length per Circuit c cece eens sence 70 Header Parameters 20 iia tsi oe hee el pe aes eee 71 Number of LIS atada in eevee des dane 72 Pipe S120 ssc 2602s y Sa es a E 72 Header Length Average Branch Length o ooonocncncccnc 72 Head Loss per 100 feet 0 cece cceec ec eeeec eee eeeee ee eneens 72 A AS cata aCe Re A IO 72 A CPR CADE OER 6 PALER REAR CBRE IEEE GC 73 REUS A Sb atonal Henne A eae ees obi 74 Reporting Sec ia da Ma eos Meath ie od 75 Chapter 7 Repo iepenens oraaa raaraa aaa eaea ncn CL Overview The Report Preview Wind adas 77 Project Reportan Dat a IS AA hatha eh coats hesebesh ev A E sn the coek eee ews ont eos 78 Calculation Results 2 iaa 78 Input Parameter Sinsen generen Geet e a 78 Comment Sasae aE e e E e E EEEE ET N e E A END 79 LOMO REPO AEA ATEEN clado RAN atlas de eae ee eae ued tenia 79 Concise A A estate obi a oR vlad edule e aa aae a ee E 80 Equipment List o e a e T a a E a e Eai
47. er during the design process Parameters are placed into sections with names taken directly from the panels in the design modules The filename of the zone file associated with the project is listed under the Loads heading 78 CHAPTER 7 Reports Comments This section at the end of the report is reserved for any additional information that the designer would like to include with the project Zone Reports Zone or loads reports are printed directly from the Loads modules They include only the project information and data from the zones presented in different formats Five different zone reports exist containing complete or specific information about the zones Zone reports work in conjunction with project reports but are actually a separate entity They are representative of the actual installation rather than the heat exchanger portion of the system Zone delineation loads and equipment are separate from the heat exchanger system It is for this reason that the designer would necessarily want to view and consider this information apart from the specific heat exchanger details For example if the design is a building the zone reports will cover everything within the building while the project report essentially will contain information about everything outside or external to the building A zone report is printed from the Loads panel of the Zone Manager or directly from an Average Block Loads module by clicking the printer bu
48. er receives from a third party without restriction on disclosure and without breach of a nondisclosure obligation or iii Customer develops independently which Customer can prove with written evidence Customer acknowledges that the Software is a trade secret of Gaia the disclosure of which would cause substantial harm to Gaia that could not be remedied by the payment of damages alone Accordingly Gaia will be entitled to preliminary and permanent injunctive relief and other equitable relief for any breach of this Section Limited Warranty Gaia warrants that the Software will substantially conform to its published specifications for a period of thirty 30 days from the later of receipt of the Software or receipt of access to the Software Gaia further warrants that the media on which the Software is contained will be free from defects for a period of thirty 30 days from the later of receipt of the Software or receipt of access to the Software This limited warranty extends only to Customer as the original licensee Provided that a Customer has notified Gaia of such substantial non conformance or defect during the applicable warranty period and b Gaia has confirmed such Software or media to be substantially non conforming or defective as Customer s sole and exclusive remedy and Gaia s and its suppliers entire liability under this limited warranty Gaia will at its option repair replace or refund the Software free of charge Except as ex
49. es that Gaia shall have no obligation to provide any Upgrades under this End User Agreement If Upgrades are provided Customer acknowledges and agrees that i Customer has no license or right to use any such additional copies or Upgrades unless Customer at the time of acquiring such copy or Upgrade already holds a valid license to the original Software Notices of Proprietary Rights Customer agrees to maintain and reproduce all trademark copyright patent and notices of other proprietary rights on all copies in any form of the Software in the same form and manner that such trademark copyright patent and notices of other rights are included on the Software Except as expressly authorized in this End User Agreement Customer shall not make any copies or duplicates of any Software without the prior written permission of Gaia Customer may make such backup copies of the Software as may be necessary for Customer s lawful use provided Customer affixes to such copies all trademark copyright patent and notices of other proprietary rights that appear on the original Proprietary Rights Customer shall own the physical media on which the Software is recorded but the Software is and will remain the sole and exclusive property of Gaia Gaia s rights under this Section will include but not be limited to i all copies of the Software in whole and in part and ii all Intellectual Property Rights in the Software For purposes herein Intellect
50. eynolds number to represent the different types of flow with values of Re 1600 3150 and 10000 for laminar transition and turbulent respectively The calculations also use average viscosity values and the Prandtl number for water taken at a temperature of 70 F 55 CHAPTER 5 The Horizontal Design Module y Horizontal Design Project 2 Results Fluid Soil Piping Configuration Extra kw Information Pipe Parameters Pipe Size in 25mm Pipe Type SDR11 En Flow Type Turbulent Check Pipe Tables Fig 5 3 Piping Panel Contents Using the standard expression for resistance of a hollow cylinder Incropera and DeWitt 1990 the program calculates an approximate value for the pipe resistance It assumes HDPE pipe with a conductivity of 0 225 Btu h ft F The pipe resistance varies with the pipe style and flow The user can select the size and type of pipe from the appropriate selection boxes If another pipe diameter is required contact support Note By pressing the Check Pipe Tables button the Pipe Properties tables will open Soil Input parameters relating to the soil are located in the Soil panel as shown in figure 5 4 These include the average ground temperature the soil thermal properties and the ground temperature corrections at a given depth 56 CHAPTER 5 The Horizontal Design Module y Horizontal Design Project 41 Results Fluid Soil Piping Configuration Ex
51. f the antifreeze are used for the calculation of the heat pump outlet temperature which in turn is used for the trench length calculation Additionally the viscosity of the solution may affect the flow type in the pipe which was selected on the U Tube panel The designer must be aware of any changes made Note Since solution properties vary considerably and non linearly with type and percentage of additive Ground Loop Design does not include detailed automatic antifreeze information for all conditions Generalized tables of data may be found in the Fluid Properties tables Results All results for both the heating and the cooling calculations can be viewed at any time on the Results panel After all data has been entered or any changes have been made the user can calculate interim or final results using the Calculate button A sample screen for this panel can be seen in figure 4 8 The two lists on the Results panel are for heating and cooling Although all of the numbers shown are valid and respond to changes the side with the longer required length is printed in bold type so that it stands out The longer length determines the installation size and for this reason the shorter length system results lose relevance In fixed length mode since both heating and cooling are of equal length neither side is highlighted 47 CHAPTER 4 The Borehole Design Module Calculate Button Results The reporting section is separated i
52. ge values entered into the lower section of figure 3 4 are determined from annual loads data for the system being designed They represent the percentage of the year that the system would be running if operating at full load and are a measure of the system running time 0 means the system is not running at all during the year and where 100 means the system is running at peak load 100 of the year This system represents the total energy input to the ground in terms of the peak load Below is an example of how to calculate the Annual Running Time Example Calculation Total annual cooling kBtus 18500 kBtu peak 25 kBtu hour 18500 kBtu 25 kBtu hour 740 hours 740 hours 8760 hours year 8 5 annual running time If exact values are not available an estimate should be made with regard to the expected running time of the unit in each particular zone Estimates of time must be reduced of course from actual running time since the annual running time represents the running time if the system were operating continuously at full load which is not generally the case Remember that although the vertical bore length calculation results are not extremely dependent on the running hours within one zone for multi zone designs the total number of running hours across the zones can certainly affect the required bore length The user should attempt to enter the annual running time as accurately as possible 26 CHAPTER 3 Loads a
53. gement and hourly heat variations Kavanaugh and Deerman 1991 12 CHAPTER 1 Ground Loop Design Overview However time step based rates of rejection and extraction also previously were discussed in some depth by Parker et al The two Slinky options available on the Configuration panel partially are based on the above formalism Because of the complexity of the solution to the heat transfer equation for coiled loops of pipe the design procedure used for the Slinky options is actually only a theoretical approximation This approximation is recommended in Closed loop Geothermal Systems Slinky Installation Guide and is based on a specific set of tests conducted on 36 diameter Slinky coils Jones 1995 In the approximation the program first calculates the total trench length required for a single U Tube buried at the specified trench depth It then divides the calculated length by 250 ft and multiplies the result by a factor determined from both the run fraction and the Slinky pitch distance between adjoining loops The horizontal Slinky configuration employs the same calculation procedure as that of the vertical However in the case of the horizontal Slinky the U tube depth is lowered such that the average depth of the vertical Slinky would be equal to that of a flat horizontal Slinky The pitch and run fraction function is obtained from a two dimensional interpolation over the surface determined from the experimentally de
54. ght Check Fluid Tables Fig 5 5 Fluid Panel Contents Solution Properties Solution properties are also included in the Fluid panel A reference label is included so that the designer knows the percentage of antifreeze and antifreeze type however this reference label is not currently linked to the other input parameters The user first selects the fluid type and then selects the desired freezing temperature Ground Loop Design automatically incorporates the specific heat and density for the fluid selection into the calculations The specific heat and density values of the antifreeze used can be found in the Soil Properties tables that can be accessed from the Tables dropdown menu The specific heat and density values of the antifreeze are used for the calculation of the heat pump outlet temperature which in turn is used for the trench length calculation Additionally the viscosity of the solution may affect the flow type in the pipe which was selected on the Piping panel The designer must be aware of any changes made Note Since solution properties vary considerably and non linearly with type and percentage of additive Ground Loop Design does not include 60 CHAPTER 5 The Horizontal Design Module detailed automatic antifreeze information for all conditions Generalized tables of data may be found in the Fluid Properties tables Results All results for both the heating and the cooling calculations can be vie
55. gn module using the Design Studio Units menu and then open a new report Project Reports A project reports may be opened at any time from the Design Studio File menu by selecting Print One project report for each heat exchanger module is available The report contains full project information The report does not print automatically but instead creates the report preview window in which the report can be reviewed prior to printing Printing can be done by clicking on the printer icon in the upper left hand corner of the report preview window In general project reports contain several main sections e Information e Calculation Results e Input Parameters e Comments Information This section contains the information from the design module s Information panel The project and designer s names dates client s name and address etc appear here This section is included at the top of every report Concise reports only include the project name and start date Calculation Results This section lists the results of the calculations and essentially is the same information shown on the Calculate panel of the design module The most important results such as the total length of pipe required are highlighted and boxed in order to stand out from the background The report presents results of both the heating and the cooling calculations Input Parameters This section contains all of the parameters entered by the design
56. hen multiplied by the flow rate in gpm ton chosen on the Fluid panel It represents the flow rate from the installation out to the buried pipe system Printing Reports A report of the active project can be printed at any time from the Design Studio using the toolbar print button or from the File menu gt Print Information printed includes all of the input parameters from the design module along with the associated results The zone and loads information is not included with the report and must be printed separately from the Loads panel The filename of the zon file associated with the project report is also listed on the reports More information on reports can be found in Chapter 7 References Francis E Editor Refrigeration and Air Conditioning 3 Edition Air Conditioning and Refrigeration Institute p 186 Prentice Hall New Jersey 1997 Incropera F and Dewitt D Introduction to Heat Transfer 2 Edition p 456 p 98 John Wiley and Sons New York 1990 Paul N The Effect of Grout Thermal Conductivity on Vertical Geothermal Heat Exchanger Design and Performance M S Thesis South Dakota State University 1996 49 CHAPTER 5 The Horizontal Design Module CHAPTER 5 The Horizontal Design Module This chapter describes the features and operation of the Horizontal Design module This module is used in the design of near surface horizontal systems It is one of the three design modules included with Ground Lo
57. his module is used in the design of vertical borehole systems It is one of the three design modules included with Ground Loop Design Overview A design is only as good as the quality of the data that goes into it This is certainly the case with the Ground Loop Design Borehole Design module Although Ground Loop Design utilizes the best theoretical models available today the most accurate results will naturally result from the most accurate input parameters Because the calculations conducted here involve the combination of a large number of input parameters care must be taken to assure that proper values are verified before use Assuming that reasonable values are provided to the software the software will provide reasonable results General Features To aid in the data entry process the Borehole Design module in Ground Loop Design consists of a set of panels grouped by subject through which the designer can enter and edit the input variables efficiently For example parameters related to the soil are listed on the Soil panel while piping choices are listed on the U tube panel The idea is that everything related to a project is presented simultaneously and is easily accessible at any time during the design process 36 CHAPTER 4 The Borehole Design Module The Borehole Design module includes several additional features Metric and English unit conversion Printed reports of all input and calculated data Convenient buttons to br
58. ial 55 Piping Parametros 55 DOU ss tidak E A sna tekstas E E E IAN 56 Undisturbed Ground Temperature cceceeceecee ee eee ee eaeaes 57 Soil Thermal Properties 0 cccccececeeceeceeneeneeeeneeneneeeeeneeas 57 Ground Temperature Corrections at Given Depth ooooon nnnnnnnnn n 58 Regional Air Temperature SWIN8 ooooocccccncncncnccnncincnnncs 58 Coldest Warmest Day in Year cceceeceeeeeeneee ene ee es 58 Fluid A A Ads eae atte aifns Stare UBD Milad Sites thea oh Eea 59 Design Heat Pump Inlet Fluid Temperatures ceceeeeeee eee 59 Design System Flow Rate cccecceeeceecencee ences eeeneneeneeneeas 59 Solution Properties cccececeececeec ence eee eee eens eens eee eeaenes 60 RESUIIS to ht att eE 61 Reporting SectiOtsc cenie de ase cia 62 Printing REPorts vce cscs sae A A CEE Red 62 Chapter 6 The Surface Water Design Module cscssseeereees 64 OEI ii 64 General Features isis dispo iia dia 64 Open me A O ad neabaak ee 65 New Projects tasa pottladauh datada doo de ocio land 65 Ex1sting Projects critica meo blidos edo idad dada as rbd daa 65 SAA A O weamtetad seh aeae aeaeaie 65 Typical Operation attends 66 Before You Beinen O stad asled adtensiax wstae patesactadas adeants 66 iii CONTENTS Entering Data into the Tabbed Panels 0 0 cc cceec cence cence ee ee eenteee eae ee ee eaeeneaee 67 Surface Matt cs 67 Surface Wat
59. imary heat pump family utilized by the designer for a particular project Although this is the primary series other pumps may still be selected for certain zones using either the Select button or by defining a custom pump To choose a pump series select a manufacturer followed by the desired series of that manufacturer A list of available pumps appears in the list box Inlet Load Temperatures Values for the initial inlet load temperatures for both water to air and water to water pumps may be entered in the appropriate boxes If necessary these values may be changed for individual pumps in the Loads panel For water to air pumps WB refers to Wet Bulb and DB refers to Dry Bulb temperatures 31 CHAPTER 3 Loads and Zones Pump Continuous Update Feature The Update Reselect Current Pumps control is called automatically when changes are made to either the inlet source temperature or the system flow rate from within the Zone Manager or the design modules In this way the designer does not have to worry about updating the pumps already matched to zones in Ground Loop Design However the designer must be aware that sometimes this may result in a new pump size assignment due to capacity changes related to variations in temperature or flow If this is problematic custom pumps may be used to lock pump values into a zone However for proper modeling any customized pumps must be edited separately by the designer after
60. ince Ground Loop Design cannot determine which project should be disconnected The link status lights in the corners of the modules indicate when links are broken Link status lights are described in more detail below ET Studio Link Status Lights Studio Link status lights are used to indicate when links are made when data transfer occurs and when links are broken They are located in the lower left hand corner of the design modules and the lower right hand corner of the loads modules Bro LO Connection Established First Light from Left The light furthest to the left indicates both whether or not a connection is established and the type of connection Ifthe light is off no connection is established Magenta indicates a link to an Average Block Loads module while light blue indicates a link to a Zone Manager loads module 33 CHAPTER 3 Loads and Zones CEC Receiving Data Second Light from Left The second light from the left indicates when the module is receiving data from the other module It is green in color Sending Data Third Light from Left The third light from the left indicates when the module is sending data to the other module It is yellow in color ECHA Broken Connection Rightmost Light The light on the right turns red whenever a connection is broken It turns off again when connections are reestablished Importing Loads Data From External Programs With Ground Loop Design users easily can import
61. ing Series Selection in the Heat Pumps Tabbed Panel Figure 3 8 Shows the Zone Manager opened to the Heat Pump tabbed panel This panel is used to specify the working series for all of the automatic selection features described for the Loads tabbed panel In the Heat Pump tabbed panel the user simply selects the pump series that he or she intends to use for the matching session The selection may be changed at any time without affecting AN previously automatically selected units However if the Auto Select All 30 CHAPTER 3 Loads and Zones Pumps button on the Loads panel is pressed every zone will be replaced with the current working series Additionally in this panel the user may define an inlet load temperature to be used in any automatic selection Choosing the Active Series The active heat pump series is the series of heat pumps used by the Auto Select features in the Loads panel Heat Pumps Loads mHeat Pump Selection And Design Load Temperatures m Select Heat Pump Manufacturer And Series Florida Heat Pump y EV Series y Pumps Available in this Series Design Heat Pump Inlet Load Temperatures Cooling WB 67 0 deg F Heating DB 70 0 deg F Inlet Air Temperatures Water to Air Pumps Cooling 55 0 degF Heating 100 0 deg F Entering Water Temperatures Water to Water Pumps Fig 3 8 Heat Pumps Tabbed Panel It represents the pr
62. ing up tables and calculators A Calculate button used to refresh the calculations Opening Projects There are two ways to open Borehole Design projects One is by using the New Borehole command from the Design Studio File menu or toolbar and the other is by opening an existing Borehole Design project gld file Files cannot be opened if other modules with the same name are already open As many files can be opened as the system s memory permits FF New Projects New projects may be opened at any time from the Design Studio by choosing New Borehole from either the Design Studio File menu or the toolbar New projects open with standard parameter values that must be edited for new projects The module opens directly into the Information panel through which the designer enters information about the new project In new projects no loads files zon are loaded The user must create a new loads file or open an existing loads file into one of the loads modules Links may be established using the Studio Link system described in Chapter 3 Existing Projects Existing projects may be opened at any time from the Design Studio by choosing Open from the Design Studio File menu or toolbar The file automatically opens into a new Borehole Design Project module If a loads file zon is associated with the loaded project the loads file automatically will be loaded into the appropriate loads module and opened along wi
63. itor like those distributed 85 CHAPTER 8 Tables and Reference Files with common browsers or with a simple text editor They must however follow a certain format and have a htm or html extension Editing Existing Files Existing files may be edited by simply opening up the original file into a text editor or HTML editor making changes and then saving the file again For example if a user wishes to add a new pipe table to the list he or she first will create the table i e PipeTable4 html and then will add a link to it on the PipeTables html file Additionally if the user wishes to add additional information to an existing table or figure he or she only has to open the appropriate HTML file in a text editor or HTML editor and make and save the desired changes For example if adding a new link PipeTables4 html to the PipeTables html file one might add this new link with the name Table 4 New Pipe Table by typing the new link at the end of the PipeTables html file into a text editor as follows the added section is in bold type lt li gt lt a href PipeTable3 html gt Table 3 Required Flow Rates to Achieve 2ft s SDR 11 Pipe lt a gt lt li gt lt ul gt lt li gt lt a href PipeTable4 html gt Table 4 New Pipe Table lt a gt lt li gt lt ul gt lt body gt lt html gt PipeTables html edited version Making a Table A new table can be made at any time by crea
64. k eect ekg O pO EVEREST GI Eig is 45 Design Heat Pump Inlet Fluid Temperatures ceeeeeee ee eee 46 Design System Flow Rate ccecceceecec eee eee scene eeeneeeeeaeeaenes 46 Solution Properties 0 ccececeececeec ence e E E E E E 47 Results orci A E A E E 47 Calculate Button ResultS ooooooccccccncccncnccncncncncncncninccncncnnons 48 Printing Reports iio E 49 Chapter 5 The Horizontal Design Module o oooccoccoccccronononor OO Over Wisin tdi Nese dabei 50 General Features ninia ios 50 Opening Project uta ias ahead nin wea aio 51 New Projets coca etoen r en cit 51 Existing Projects iia 51 SAVING A Goch he ens E EEEE V E chutes koe eee 51 Typical OP nidad ts 52 Entering Data into the Tabbed Panels 0 0 eccece cee ce cence eee eeenteeeee eens eae eaeneees 52 Configuration gi sc evs Sia stage kN Rees EER A i EE 52 A ote tocaioiatadicna E A eis eestadicde OEE S 52 Pipe Configuration in Trench cc cceceececeee eee enentee eee een enes 53 Straight Pipe Configurations eccceeceecereee ene eeneeeeneeneeaes 53 Single Pipe Vertical Alignment cccceeeeee eee eeees 53 Two Pipe Vertical Alignment ccceecee ene rreren 54 Three Pipe Vertical Alignment 54 Slinky Pipe Configurations 0 0 cccceceeceeee eee eeeetee ene en een enes 54 Vertical SlMk Yui aia 55 Horizontal ink Yoco irte da 55 PIDE r
65. kW Information Girt Circuit Parameters Circuit Pipe Size E in 25 mm Number of Parallel Circuits Cooling 4 Heating 2 Circuit Style C Coil e Slinky Circuit Head Loss per 100 feet Cooling 14 fthd Heating 15 ft Ad Extra Equivalent Length per Circuit 33 1 ft Fig 6 2 Piping Circuit Panel Contents Circuit Parameters Circuit Pipe Size This is the size of the pipe used in the primary heat transfer circuits Although larger pipes offer better heat transfer designers generally prefer smaller sizes 3 4 1 because of ease of handling and lower pipe costs Number of Parallel Circuits This is the number of parallel circuits required to maintain the required minimum flow rates defined by the designer If the number of circuits entered here is greater than the allowed number of circuits this value will be overwritten automatically with the limiting value when the calculations are performed 69 CHAPTER 6 The Surface Water Design Module Even if the circuits are split into equivalent groups for example three groups with ten circuits each the total number of parallel circuits the smallest unit will not change Circuit Style Both loose bundled coils and slinky spread out styles are available If extensive spacers are used in a coil style arrangement the slinky model may provide more accurate results but the loose coil option will provide the more conservative results
66. ll work without the browser but the data reference files may not be accessible 15 CHAPTER 1 Ground Loop Design Overview Metric and English reference files are included with Ground Loop Design These files aid in the correct verification and entry of the various parameters The three main topics design aids currently included under the Tables menu in the Design Studio are Fluid Properties Soil Properties and Pipe Properties A convenient Conversions table with metric English conversions in two different formats is included for reference as well Reference files can be opened and left as open windows on the desktop and the user can refer to them as necessary during the design process Realizing that designers and engineers have their own preferred resources Ground Loop Design employs the HTML browser model so that the user has ultimate control over the reference files The designer simply creates a basic HTML file containing customized data pictures graphs charts etc and then modifies the included top level HTML files to link to their pages The system requires a very basic knowledge of HTML but it offers an extremely flexible system for user customization Detailed information on reference files and sample HTML can be found in Chapter 8 Program Help and Support Ground Loop Design contains a comprehensive searchable database of help topics Access this feature from the Design Studio Help menu Through the Help menu it is also
67. loads data from both loads programs such as the GeoXergy Plug In and Excel files directly into the loads modules Using the Import Excel Button for the GeoXergy Plug In and Excel To import data from the GeoXergy Plug In and Excel files follow these guidelines Ground Loop Design expects the Excel data to be in the following column order and units Cooling Heating Peak kBtu or kW Annual Running Time To import the Excel data simply highlight the two columns and two rows in the Excel spreadsheet that contain the data and copy them onto the clipboard Ctrl C Note highlight only the numeric data DO NOT highlight the column and row descriptions Then click on the Excel icon The data will be imported 34 CHAPTER 3 Loads and Zones Note that it is possible to import a single column of data Following the column order listed above put the single column of data in the correct position Fill the remaining columns with zeros and then copy all four columns to the clipboard Surface Water Design Loads The Surface Water Design Module does not require the loads input detail of the other design modules Since there is no long term build up of heat in the water the only values that are actually required are the peak demand of the installation 35 CHAPTER 4 The Borehole Design Module CHAPTER 4 The Borehole Design Module This chapter describes the features and operation of the Borehole Design module T
68. lues that must be edited for new projects In new projects no loads files zon are loaded The user must create a new loads file or open an existing loads file into one of the loads modules Links may be established using the Studio Link system described in Chapter 3 Existing Projects Existing projects may be opened at any time from the Design Studio by choosing Open from the Design Studio File menu or toolbar The file automatically opens into a new Surface Water Design Project module If a loads file zon is associated with the loaded project the loads file will be loaded automatically into the appropriate loads module and opened along with the project file However if the associated loads file cannot be found the user will be notified and the automatic file loading will not occur Saving Projects Projects may be saved at any time using Save or Save As from the Design Studio File menu or by clicking the save button on the toolbar When the user 65 CHAPTER 6 The Surface Water Design Module closes the program or module the program automatically asks the user if he or she would like to save the project file Typical Operation Although each user has his or her own style the typical operation of the Surface Water Design module would include the following steps 1 Enter Loads and select pump in either the Average Block Loads module or the Zone Manager module 2 Forma link between the loads mod
69. luid Soil U Tube Pattern Extra kw Information CHAPTER 1 Ground Loop Design Overview Fig 1 1 Borehole Design Panel List Using these seven panels Results Fluid Soil U Tube Pattern Extra kW and Information the user enters the project specific information After the user enters all parameters the software calculates results based on the input data Within this framework it is straightforward and easy to make changes and conduct new calculations In Residential Version 5 1 the Borehole Design module allows for two types of design methodologies fixed temperature and fixed length designs Fixed temperature designs should be familiar to users that upgraded from earlier versions of GLD Fixed temperature refers to the design process in which users specify target inlet temperatures designers set or fix the temperatures themselves and then have the program calculate results such as the required bore length the outlet temperatures and the coefficient of performance COP etc based on the input data With fixed length designs designers specify the required borefield length by inputting the number of boreholes in the design and then defining the borehole length fixing the total design length After entering these data as well as the other design parameters the software calculates results such as the inlet and outlet temperatures and the coefficient of performance COP etc based on the input data The fixed le
70. mation that meets the user s needs User added files can supplement or replace the data reference files already provided with Ground Loop Design Metric English Units CHAPTER 1 Ground Loop Design Overview One of the intrinsic features in Ground Loop Design is the English metric unit conversion capability The English metric option can be used not only to compare values but it also can be used to quickly make use of specific equipment or loads data supplied in only one format Because the reports and data reference files automatically recognize the selected units users can obtain different reports and data lists depending on the state of the Design Studio Sharing of project information with designers contractors subcontractors architects and building owners is now a straightforward process Internationalization The final major feature of Ground Loop Design is the international component Because the program is multi language capable users easily can communicate accurate results and design parameters across borders even when the designers are not proficient in the technical language of their foreign counterparts Currently French Japanese Chinese Korean Italian Spanish Russian Czech Lithuanian and Romanian versions are available Zone Loads Module Introduction The zone loads module provides an organized method for entering the heat gains or losses for an installation In the zone loads module users also match heat
71. mp epee Pump Series EY Series Pump Type Water to Air Nominal Flow 1600 CFM Inlet Air Temperatures and Flow Rate Load J EAT Cooling WB 67 0 degF Heating DB 70 0 degF Flow Rate Cooling 1699 CFM Heating 1600 CFM Fig 3 7 Pump Details Panel Clear Pressing the Clear button clears the current pump in a zone All values are reset to the initial state allowing the user to reselect or enter a pump for the zone Custom Pump Customization If the designer must include a heat pump unit that is not stored in Ground Loop Design s Heat Pump Database he or she may add customized pumps simply by entering values directly into the boxes on the pump selection section of the zone data window When the user does this and overrides the automatic selection features a check appears next to the Custom Pump label indicating that the pump information is from an external source The details section will no longer contain information about the pump manufacturer series or type The calculation portion of Ground Loop Design will require at least the capacity and power data to utilize the pump properly The actual COP used in the calculations is determined from the capacity and the power not the input text box Other information may be added for the designer s reference 29 CHAPTER 3 Loads and Zones Note When a custom pump is included its values will remain unchanged during A the designing process Vari
72. n a link will be established with that module If more than one type of loads module is open Ground Loop Design will query the user for his or her linking preference 32 CHAPTER 3 Loads and Zones Alternative systems for linking exist but they are more indirect For example if only one unlinked design module is present a link may be established from any open loads module since Ground Loop Design automatically recognizes the user s intention If more than one unlinked design module exists however pressing the link button from an active loads module will have no effect The link status lights in the corners of the modules indicate when a link has been formed Colors indicate the type of link Link status lights are described in more detail below 3 Unlinking To break a link between modules simply activate click on the design module to be disconnected and click the Unlink button on the toolbar Equivalently the user can choose Unlink from the Ground Loop Design Loads menu The link will be broken and all related loads information for the design module will be cleared However the information still exists in the loads module and can be recovered by linking again if necessary If only one design module is linked to a particular loads module unlinking from the loads module is also possible If more than one linked design window is open however clicking the unlink button from a loads module will have no effect s
73. n the zone list changes the working zone Using the list the designer can bring up and modify any particular zone by clicking on its name An essentially equivalent but more compact summary of the input data can be obtained in the Summary View obtained by clicking on the Summary View toggle button Different representations of zone data can also be printed as reports Managing Zones in the Loads Tabbed Panel The buttons along the top of the Zone Manager are used to work with the zones A closer view is shown in figure 3 2 23 CHAPTER 3 Loads and Zones Dog bs E sue 2 Fig 3 2 Zone Manager Control Buttons The five buttons on the left side are zone editing controls and they include New Copy Remove Renumber and Clear A Summary view of all the zones can be obtained by hitting the sixth or Summary View toggle button The next three buttons are the Open and Save buttons for opening and saving the zone files and the Print button for printing various zone reports The final two buttons on the far right are for pump selection across the entire set of zones and include Auto Select All and Update Reselect which are discussed in more detail below LY New and Copy A new zone may be created at any time from the Loads panel by clicking the New button Identical zones may be created from any existing zone by bringing up that zone s data window and clicking the Copy button 1 Remove and Clear Zones also can be deleted fr
74. ncluded in Ground Loop Design s internal list of pumps Heat Pump Specifications at Design as and Flow Rate Pump Mame Custom Pump PO40Y ro e Cooling Heating Capacity kBtufHry 42 0 37 8 Select Power tkwi 260 2 35 FERICOP 16 2 47 Details Flow Rate gpm 6 3 qo Partial Load Factor 0 60 O 95 Fig 3 5 Sample Pump Selection Section with Data 27 CHAPTER 3 Loads and Zones Auto Select This option is by far the easiest method of matching a pump to the loads in a particular zone By clicking the Auto Select button Ground Loop Design utilizes the information stored for the active pump series and determines which pump within the list is best suited to the zone in question If the listed pumps are too small for the zone loads the software increases the number of pumps of each size until an acceptable match is achieved The pump selection process uses information from the Zone Manager loads module This includes the chosen inlet source temperature the flow rate the heat pump series and the initial inlet load temperatures The flows and load temperatures can be entered at the bottom of the module and the active heat pump series and load temperatures may be changed on the Heat Pumps tabbed panel Manual Select If an automatically selected heat pump is for any reason undesirable or a different pump series from the same manufacturer or even from a different manufacturer is required the Se ect button may be use
75. nd Zones Equivalent hours are unnecessary for a surface water design since long term buildup effects are unimportant If a loads module is linked to a Surface Water Design module the hours will not be visible Pump Matching and Selection Every zone has heat pump equipment associated with it Equipment matching and selection is done within the zone data window in the lower section entitled Heat Pump Specifications at Design Temperature and Flow Rate In this section the designer has three choices when matching a pump to a zone e Automatic selection based on the active heat pump series e Manual selection from a list of all available pumps e Custom input of pump data Once selected the zone retains all of the information associated with the pump chosen This information includes the pump name the number of pumps and the capacity power consumption EER COP flow rate and partial load factor in both cooling and heating modes If obtained from the list of available pumps detailed information is also available including the manufacturer and series name the pump type and the inlet load temperatures Figure 3 5 shows the pump selection section of the zone data window with sample data matched to the loads data of figure 3 4 Several buttons can be found in the pump selection section These include Auto Select Select Details and Clear A checkbox is also included to indicate when the pump is a custom pump or a pump not i
76. ne the pump power An image of the pump power calculator is shown in figure 4 3 Pump Power Calculator z 01 xj Pump Power Required Pump Power hP Pump Head 50 0 ft hd Flow Rate 100 0 gpm Pump Efficiency 80 0 Fig 4 3 Pump Power Calculator 40 er CHAPTER 4 The Borehole Design Module Pattern Information pertaining to the ground field arrangement is in the Pattern panel This includes the fixed borehole length design option the vertical boreholes pattern and the borehole separation The input screen is shown in figure 4 4 Fixed Length Mode By selecting fixed length mode the designer can specify the loop field length number of boreholes x length per borehole and have Ground Loop Design calculate the entering water temperatures When in fixed length mode it is important to note that both cooling and heating lengths are identical unlike in the fixed temperature mode where designers specify temperatures and calculate lengths When fixed length mode is not selected the program operates in fixed temperature mode in which the designer specifies the number of boreholes and the target inlet temperatures so that the program can calculate borehole lengths Vertical Grid Arrangement The standard Borehole Design module is configured to accept equally spaced borehole patterns based on an x y coordinate system For rectangular systems users can enter the pattern directly into the rows
77. nformation The contents of the Information panel are shown in figure 4 1 All of the descriptive information related to the project is stored in this panel This primarily includes the names of the project and designer and the dates Reference data concerning the client also can be included on this page so that all relevant project information is in one convenient location In addition to generalized project information specialized comments can be included in the Comments section of the Information panel This area allows the designer to make any notes particular to the specific project that may not necessarily fit under any of the other topics provided 38 CHAPTER 4 The Borehole Design Module All of the data in the information panel is optional but completing the page is recommended for the sake of organization Reports utilize the project information as a way of distinguishing one project from another Except for the dates the information panel input boxes contain only text and any desired format may be used when filling out the form ES Borehole Design Project verticalsampleforManual Results Fluid Soil U Tube Pattern Extra kw Information l Project Information Project Name Designer Name Date Project Start Date Borehole Design Sample Project B Engineer 10 5 2007 s hors 2007 y Client Name ABC Corp Address Line 1 1333 Any St Address Line 2 Suite 2200 City State Zi
78. ng and cooling modes Kavanaugh 1997 Ground Loop Design uses a polynomial fit of this experimental data to determine the amount of pipe necessary for different loading conditions Additionally coefficients are used to take into account the effect of the heat transfer in the lengths of the header and the branch piping that are in both the water and the soil between the installation and the submerged circuits The program combines all factors so that the loop system provides the source inlet temperature at the heat pump requested by the designer Because the circuit layout is of primary importance to the designer concerned with pumping losses the head loss estimation feature for different piping configurations is included in the Surface Water Design module Users can quickly explore different layouts to determine the optimum design in terms of both heat transfer and circulation pump energy losses A description of some of the calculations and the input data can be found in Chapter 7 of the book Ground Source Heat Pumps Design of Geothermal Systems for Commercial and Institutional Buildings by S P Kavanaugh and K Rafferty 1997 Additional Modules Ground Loop Design s Design Studio has the potential for additional modules that may be included in later versions These modules would also be able to take advantage of the Design Studio s heat pump and loads models 14 CHAPTER 1 Ground Loop Design Overview Reports Ground L
79. ngth feature is well suited for designing when land resources are limited when drilling costs beyond a certain depth become exorbitant when a designer wishes to quickly reverse engineer a malfunctioning system etc A more complete description about how to enter data and perform calculations in the Borehole Design module is provided in Chapter 3 Theoretical Basis The theory behind the vertical borehole module is based on the cylindrical source model and allows for quick but accurate length or temperature calculations based on limited data input The vertical bore length equations used in the Borehole Design module are based upon the solution for heat transfer from a cylinder buried in the earth The method was developed and tested by Carslaw and Jaeger Carslaw and Jaeger 1947 The solution yields a temperature difference between the outer cylindrical surface and the undisturbed far field soil temperature Ingersoll suggested using the equation and its solution for the sizing of ground heat exchangers in cases where the extraction or rejection occurs in periods of less than six hours where the simple line source model fails Ingersoll 1954 The borehole module s equations include the suggestions of Kavanaugh and Deerman who adjusted the 10 CHAPTER 1 Ground Loop Design Overview methods of Ingersoll to account for U tube arrangement and hourly heat variations Kavanaugh and Deerman 1991 It also employs the borehole resistanc
80. nto four subsections The first deals with the bores including the total length the borehole number and the borehole length for one bore A common way to adjust the borehole length to a desired value is to change the borehole number or pattern on the Pattern panel EL Borehole Design Project 1 Results Fluid Soil U Tube Pattern Extra kw Information Calculate COOLING HEATING Total Length ft 607 8 771 1 Borehole Number 3 3 Borehole Length ft 202 6 257 0 Unit Inlet F 80 0 35 0 Unit Outlet F 90 3 29 2 Total Unit Capacity kBtu Hr 62 6 51 5 Peak Load kBtu Hr 25 0 40 0 Peak Demand k 2 7 4 3 Heat Pump EER COP 13 4 3 5 System EER COP 9 1 27 System Flow Rate gpm 6 3 10 0 Fig 4 8 Results Panel Contents The second subsection of the report lists the heat pump inlet and outlet temperatures of the circulating fluid The third subsection lists the total unit capacity the peak loads and demand of all the equipment and the calculated heat pump and system efficiencies The peak load is the maximum and is determined from whichever time period across all the zones has the highest load The peak demand includes all pumps and external energy requirements including those listed in the Extra kW panel 48 CHAPTER 4 The Borehole Design Module Finally the system flow rate is listed in its own subsection The system flow rate is calculated from the peak load divided by 12 000 Btu ton and t
81. of Microsoft Corporation Netscape Navigator is a registered trademark of Netscape Corporation The Ground Loop Design Residential Version 5 1 User s Manual Originally printed in January 2008 Printed in USA Part No GGENG 1106 Visit our Web site at http Awww gaiageo com END USER SOFTWARE LICENSE AGREEMENT PLEASE READ THIS END USER SOFTWARE LICENSE AGREEMENT End User Agreement CAREFULLY BEFORE USING THE SOFTWARE BY USING THIS SOFTWARE YOU ARE AGREEING TO USE THE SOFTWARE SOLELY IN ACCORDANCE WITH ITS INTENDED USE AND YOU ARE CONSENTING TO BE BOUND BY THIS END USER AGREEMENT IF YOU DO NOT AGREE TO ALL OF THE TERMS OF THIS END USER AGREEMENT PROMPTLY RETURN AND DO NOT USE THE SOFTWARE Single User License Subject to the terms and conditions of this End User Agreement Celsia LLC doing business as Gaia Geothermal Gaia and its suppliers grant to you Customer a non exclusive non transferable dongle based license to use the Ground Loop Design TM software program in object code form and all related materials included herewith including written materials binders and other containers hereinafter the Software on supported operating systems Use Upon a receipt of full payment by Gaia or a Gaia authorized reseller of the applicable license fees Customer will be able to use this Software pursuant to the limitations set forth herein Limitations Customer s full use of this Software is limited to the number
82. om the list Any zone can be removed from the list by bringing up the zone s data window and pressing the Remove button To delete all of the zones in the list press the Clear button Iie Renumber If several zones are added or removed from the list click the Renumber button to reorganize the zones This button renumbers the existing zones from one starting with the first zone in the current list Bl Summary View Toggle Button With the Summary View toggle button the user can at any time simultaneously look at the group of zones This view provides lists of the heat pump data in both cooling and heating modes as well as collective information about the set of chosen pumps This information includes the peak loads and the total combined capacity the peak demand and the average efficiency of the selected equipment Although individual pumps cannot be added or removed in the Summary View changes made across the entire pump selection are directly observable A sample Summary panel is shown in figure 3 3 Note that more than one type of pump series is listed 24 CHAPTER 3 Loads and Zones m Zone Manager 3 Heat Pumps Loads Bl a ca el a g P BoreholeSample zon Return _Return_ Design Day Loads MBtufHr Capacity Power COP 15 x Zone Pump 8 12 12 4 4 8 8 8 MBtu Hr kw EER PLF 1 EV048 2 62 0 89 0 0 0 0 0 93 5 7 5 12 5 95 W 2 EVO48 2 58307 BM NO Ou 2995 Fes 125 91 3 EVO48 1 46 0 36 0 21
83. ons the user Pipe Configuration in Trench Loop Pitch P 10 0 in Loop Diameter D 36 0 in Fig 5 2 Slinky Variables 54 CHAPTER 5 The Horizontal Design Module may define the pitch and diameter of the Slinky Because of the limited model employed the pitch must be between 10 and 56 inches and the diameter must be 36 inches See figure 5 2 Vertical Slinky In this arrangement the slinky is placed vertically within a trench and is resting at the bottom The trench may be as narrow as the pipe and soil allow Horizontal Slinky In this arrangement the slinky is placed horizontally at the bottom of the trench The minimum trench width depends on the slinky diameter Piping The Piping panel contains all the information related to the particular pipe chosen for the buried heat exchanger The program uses information about the pipe size and flow type to determine the associated pipe resistance which ultimately is used in the length calculations The input screen for the piping panel is shown in figure 5 3 Pipe Parameters The pipe characteristics are entered in the Pipe Parameters section They include the pipe size the pipe type and the flow type As in the Borehole Design module Ground Loop Design calculates the convective resistance using the Dittus Boelter correlation for turbulent flow in a circular tube Incropera and DeWitt 1990 The calculations use average values of the R
84. oop Design s reporting features allow the designer to make hardcopies of both the data entered and the resulting calculations These reports are design records and are valuable when communicating the design to others involved in the projects Project Reports Every design module has an associated project report which can be printed at any time from the Design Studio desktop The project report contains all the project information and includes the parameters chosen the calculation results and the name of the zone file used Zone Reports A print button in the loads modules allows the designer to print the loads related information in various formats Because the zones contain information about the zones the loads and the equipment it is often necessary to obtain reports of the information in separate as well as combined documents For example at one time a designer may want to quickly see all of the zones with their loads and corresponding equipment At other times the designer may only need to see a list of the equipment for each zone Ground Loop Design offers five different zone report options including A concise zone report A detailed zone report An equipment list report A loads report A zone names report Reports are described in detail in Chapter 7 Data Reference Files To access the data reference files the user must have an internet browser present in the Ground Loop Design enabled computer The program wi
85. op Design Overview As with the Borehole and Surface Water Design modules the calculations made in the Horizontal Design module involve the combination of a large number of input parameters Care must be taken to assure that proper values are verified before use Assuming that reasonable values are provided to the software the software will provide a reasonable result General Features The Horizontal Design module in Ground Loop Design also includes a set of panels grouped by subject through which the designer can enter and edit the input variables in a straightforward and efficient manner For example parameters related to trench configuration are listed on the Configuration panel while piping choices are listed on the Piping panel Everything related to a project is presented simultaneously and easily is accessible throughout the design process 50 CHAPTER 5 The Horizontal Design Module The Horizontal Design module includes several additional features e Metric and English unit conversion e Printed reports of all input data and calculated results e Convenient buttons to bring up tables and calculators e A Calculate button used to refresh the calculations Opening Projects There are two ways to open Horizontal Design projects One is by using the New Horizontal command from the Design Studio File menu or toolbar and the other is by opening an existing Horizontal Design project gld file Files cannot be opened
86. p Phone 555 555 1212 Fax 555 555 1213 Emal This is a sample borehole project file for Ground Loop Design nytown 1711 Comments Fig 4 1 Information Panel Contents Extra kW Additional energy that is utilized by the system can be entered in the Extra kW panel The entry boxes are shown in figure 4 2 This panel is included for entire system average efficiency calculations The entry box Circulation Pumps is for the energy required by the system circulation pumps The Required Input Power is calculated from the Pump Power required by the pump s for the system in question and the average Pump Motor Efficiency It is not possible to edit the Required Input Power values directly However if the pump motor efficiency is set to 100 the Pump Power and Required Input Power will be the same 39 CHAPTER 4 The Borehole Design Module EI Borehole Design Project 1 Results Fluid Soil U Tube Pattern Extra kW Information Circulation Pumps Required Input Power 0 9 kW Pump Power 10 hp Pump Motor Efficiency 85 o Pump Power Calculator Fig 4 2 Extra kW Panel Contents Note To make a kilowatt entry in the Pump Power box switch to metric units enter the kilowatt value and then return to English units Pump Power Calculator If the pump efficiency system flow rate and head loss are known the Pump Power Calculator can be used to determi
87. pressly provided in this End User Agreement the Software is provided AS IS without warranty of any kind Gaia does not warrant that the Software is error free or that Customer will be able to operate the Software without problems or interruptions Gaia reserves the right to charge additional fees for repairs or replacements performed outside of the limited warranty period This warranty does not apply if the Software 1 is licensed for beta evaluation testing or demonstration purposes for which Gaia does not receive a license fee 11 has been altered except by Gaia 111 has not been installed operated repaired or maintained in accordance with instructions supplied by Gaia iv has been subjected to abnormal physical or electrical stress misuse negligence or accident or v is used in ultrahazardous activities The authorized distributors of the Software who are appointed by Gaia are not permitted to alter the terms of this End User Agreement in any manner Disclaimer EXCEPT AS SPECIFIED IN THIS WARRANTY ALL EXPRESS OR IMPLIED CONDITIONS REPRESENTATIONS AND WARRANTIES INCLUDING WITHOUT LIMITATION ANY IMPLIED WARRANTY OR CONDITION OF MERCHANTABILITY FITNESS FOR A PARTICULAR PURPOSE NONINFRINGEMENT SATISFACTORY QUALITY OR ARISING FROM A COURSE OF DEALING USAGE OR TRADE PRACTICE ARE HEREBY EXCLUDED TO THE EXTENT ALLOWED BY APPLICABLE LAW IN NO EVENT WILL GAIA OR ITS SUPPLIERS BE LIABLE FOR ANY LOST REVENUE PROFIT OR D
88. pumps and external energy requirements including those listed in the Extra kW panel Care must be exercised when equipment energy requirements listed in the Extra kW panel refer to only heating or only cooling types of equipment In these cases the pump efficiency could be fine but the system efficiency might be incorrect The fourth section lists the total head loss calculation results as well as the individual losses for the header and circuit pipe It does not include any losses for the heat pump equipment which must be considered separately This section is convenient for determining the optimum pumping arrangement for the system Finally the system flow rate is listed along with the flow rate in the primary header as well as the flow in the individual circuits The system flow rate is calculated from the peak load divided by 12 000 Btu ton and then multiplied by the system flow rate in gpm ton as given on the Fluid panel The primary header flow rate is calculated from the system flow rate divided by the number of primary headers The circuit flow rate is obtained by dividing the system flow rate by the total number of circuits also provided on the Piping panel Printing Reports A report of the active project can be printed at any time from the Design Studio using the toolbar print button or from the File menu gt Print The information printed includes all of the input parameters from the design module along with the associate
89. pumps to the loads automatically or manually This module can then be linked to design modules using the Studio Link system Chapter 3 With this system one type of loads and heat pump data can be used to compare multiple heat exchanger designs The zone manager can import loads data from the GeoXergy Plug In as well as from Excel files and therefore is compatible with any loads program that can output the appropriate data to Excel Zone Manager Loads Module Component style designs often are more appropriate for geothermal installations particularly when equipment is available in various sizes The units can be placed near or within the locations to be conditioned With regard to water source heat pumps it is often much easier to bring water lines to the equipment instead of providing ductwork or long load lines from a centralized source When considering geothermal applications the precision of the zone loads model is crucial because it relates directly to the extent of external heat exchanger installation Heat exchanger costs impact the overall costs of a project Additionally a unit that is called only when necessary or is well CHAPTER 1 Ground Loop Design Overview matched to a zone will be more efficient than a larger unit that may cycle more often Inputs for Ground Loop Design s Zone Manager Loads module include peak load information for each of the zones in an installation These loads data can be matched automatically to h
90. r Agreement in whole or in part without Gaia s written consent This End User Agreement shall be governed by and construed in accordance with the laws of the State of California United States of America as if performed wholly within the state and without giving effect to the principles of conflict of law No failure of either party to exercise or enforce any of its rights under this End User Agreement will act as a waiver of such rights If any portion hereof is found to be void or unenforceable the remaining provisions of this End User Agreement shall remain in full force and effect This End User Agreement is the complete and exclusive agreement between the parties with respect to the subject matter hereof superseding and replacing any and all prior agreements communications and understandings both written and oral regarding such subject matter Conventions Used in This Document The following symbols are used in this document to highlight certain information and features included in the User s Guide and Ground Loop Design software program This caution symbol notifies the user that care must be taken at the specified location This star shaped symbol highlights new features in Residential Version 5 1 The round symbol highlights suggestions for using the program more effectively or for improving designs Oe gt CONTENTS Contents Preface Before You BeGinN c ccseeccceccceeeeeeeeeeeeeeeeeseeesseeesneeneeeeeee
91. r own measurement results should fall The third table contains mean earth temperatures and other parameters for U S cities This table particularly may be useful for horizontal designs Pipe Properties Pipe properties refer to any data related to the piping The Pipe Properties tables included with Ground Loop Design are related to either the borehole thermal resistance or the pipe physical data They are listed below Table 1 Thermal Conductivities of Typical Grouts and Backfills Table 2 Pipe and Tube Dimensions Table 3 Required Flow Rates to Achieve 2 ft s SDR11 Pipe The first table provides thermal conductivities for some typical grouts The second lists the physical dimensions inner and outer diameter for common pipe sizes in various types of pipe The third although unnecessary for the associated calculations provides some convenient flow rates required for proper purging of a piping system Conversions The Conversions table has two separate lists of metric to English conversions placed together in one file As already mentioned the user can obtain multipliers for most common metric English unit changes by going through the listed conversions 84 CHAPTER 8 Tables and Reference Files Adding Customized Reference Files The user can create customized reference files by editing the existing HTML files with the table lists and making new links The process is simple and requires only a very basic knowledge of HTM
92. rams csc eeeeneeeneee eect ea enene eee eae 34 Using the Import Button for the GeoXergy Plug In and Excel 34 Surface Water Loads tai A A de seep a ir 35 Chapter 4 The Borehole Design Module ococococococcccccccnnnona DO OVERVIEW Aides loath sata ached tosh NTH conti aaa ne a aa eaaa telat ahi a Salta aches 36 General Featuresi d isis o cl oO seuss 36 Openiitig A A AE EEA A 37 INGW Projects a e a o Ws ial es 37 Existing m RO S o REEE das des 37 SAVING O E EE EEEE E TETE EE EE 38 Typical Operatioh saire neii de EA dene deta E E A RE E 38 Entering Data into the Tabbed Panels 0 c ce cccee eee ce ec ence enc eeeteneneeneneeneeeneeens 38 TAP OFINGON o eos sees sos Sek a E SS 38 Extra RW a oo east Nei ia ar Ela aT E acne a a E Me Satie aay 39 Pump Power Calculator 0c ccececceceeceene ene eeeneenteeeeeeeeaes 40 POUT State ae eM she A Jena Nad AE lta 41 Fixed Length Mode imitar poeee eee es 41 Vertical Grid Arrangement 00 cc ce ececc eee ee ene ee ee eneee eae eaeenens 41 Separation between Vertical BOr8S ooooooooooocoo ce eeeee eee eneeeeaens 41 UT UD E Bios Miter clad et rye aes eid ale docile lene led pe ae as 42 Pipe Parametros 43 Borehole Diameter and Backfill Grout Information 44 SOUL seo etal woe cei a o 44 CONTENTS Modeling Time Period c cc ece eee eee ee ee eee ene eaeeneeaenaenaens 45 PUA ache
93. reattach the dongle the program will reactivate again PREFACE How To Transfer the Program Between Computers The dongle licensing system allows the user to transfer the license from one computer to another If a user decides to transfer Ground Loop Design from one computer to another all he or she has to do is the following e Install Ground Loop Design onto the target computer e After the demo version of the program is running on the new computer attach the dongle and follow the above instructions regarding dongle driver installation CHAPTER 1 Ground Loop Design Overview CHAPTER 1 Ground Loop Design Overview This chapter is an introduction to the Ground Loop Design Residential software package It introduces new features the Design Studio the Heat Pump and Loads Modules the Borehole Horizontal and Surface Water Design Modules the reporting functions and the data reference files There is also an explanation of the theoretical and experimental basis for the program s calculations General Program Features Ground Loop Design Residential is a Geothermal Design Studio that provides the user with a freedom that single purpose software cannot offer The program is modular and permits flexibility in the designing process and customization based on designer preferences Additionally it has an English metric unit conversion option providing applicability to the widest range of equipment and customers Because
94. ribed for the Borehole Design module in Chapter 4 except for one addition That addition is the minimum required circuit flow rate in the lower Minimum Circuit Flow Rate and Solution Properties section The added section is shown in figure 6 7 As in the other modules the inlet temperatures can be viewed and modified from the expanded interface as seen in figure 6 8 Minimum Circuit Flow Rate Cooling 28 gpm Heating 42 gpm Fig 6 7 Minimum Circuit Flow Rate Section of the Fluid Panel 73 CHAPTER 6 The Surface Water Design Module Ground Loop Design uses this information in conjunction with the system flow rate to establish the maximum number of parallel circuits The flow rates required for non laminar flow for several antifreeze solutions are included as a table in the Fluid Properties set Exact values for a particular mixture may need to be determined independently by the designer Note once again that changes in the inlet source temperature or the system flow rate will cause an automatic update of the selected pumps Results There are several significant differences between the Surface Water Design module s Results panel and the Borehole Design module s Results panel These differences relate to the nature of the calculations as well as to the inclusion of the head loss calculation results Figure 6 9 shows a typical view of the Results panel Again there are two lists shown on the Result
95. s 1 Typical Uses and Users aga ene ete al System Requirements for Tastalling Ground Loop Design TAS 2 Hardware requirements cccsccescesseesceseeeeceneeseceseecsecaeecsecasesececeseceeeeeeseeeeeeeneeens 2 Software Tequirem ents 2 325526 essese se sce c gee E es 2 Operating system requirements c cece eee ence e eee ee eae eaeeaeeee 2 Internet browser requirements 0 ecece eee e cence eee en ene eneen senses 2 Installation procedi aii 3 Initial mstallation boe ideas 3 Installation of updated versions or re installati0M o oooonnnnncncnnnncn 3 Progtam Lic nsim Bi dica 3 Software License DoMgle oooooooooococoncononconcnnnncnnonncncnncnninanons 4 How to Transfer the Program Between CoMpUteTS ooooccccccccccncncocon 5 Chapter 1 Ground Loop Design Overview 0 s ssseeeeeeeeeees 6 General Program Features ccc ccc e cece eee ne ence e eee e ene n cence ne eneee ene eeeeeene eae naenegs 6 New in Residential Version 5 1 0 cceeeeceecec eee eee ee eee eee eeeaeneeaenaenens 6 The Design MU aa 7 Customization A A E E ct Metric English Units R E E ee yo E ino aE 7 Intemational Zation eeen rd iaa 8 Zone Loads Module Introduction 0 cece ee eceeseene nsec eens ea enessesnessssecsseteteeeeee O Zone Manager Loads Module cccceeee cence cee eeeee eee eeeeneee eee eeeenes 8 Design Modules A tl doo Borehole Design Module TN 9 Des bt 9
96. s panel one for heating and one for cooling Although all of the numbers resulting from both sets of calculations are valid the side with the longer length is printed in bold type so that it stands out The longer length usually determines the installation size and for this reason the shorter length system results lose relevance However in cases where the cooling and heating lengths are similar care must be taken to assure the safest design 74 CHAPTER 6 The Surface Water Design Module E Surface Water Design Project 1 Results Fluid Soil Piping Surface Water Extra kW Information COOLING HEATING Total Length ft 1788 1 1653 9 Circuit Length ft 447 0 827 0 Number of Circuits 4 2 Max Parallel Circuits Unit Inlet F Unit Outlet F 63 2 Approach Temp F 8 3 Total Unit Capacity kBtu Hr Peak Load kBtu Hr Peak Demand k Heat Pump EER COP System EER COP Total Head Loss ft hd Header Loss ft hd Circuit Loss ft hd System Flow Rate gpm Primary Header gpm Circuit gpm Fig 6 9 Calculate Panel Contents Reporting Section The surface water report has five sections The first deals with the circuit pipe and includes the total length the length for one circuit the number of circuits and the maximum allowable number of parallel circuits shown in red If the maximum allowable number of parallel circuits exceeds the actual number of circuits the act
97. termined data points provided in the Slinky manual Surface Water Design Module Description The Surface Water Design module allows the user to enter various parameters concerning the body of water lake pond river etc system As in the Borehole Module inputs are arranged in panels that relate to the type of input After the user enters all parameters the software calculates the required pipe length the circuit number the inlet and outlet temperatures and the COP etc based on the design specifications Again within this framework it is straightforward to make changes and recalculate results especially when using the expanded user interface The input information is organized into seven panels shown in figure 1 3 Results Fluid Soil Piping Surface water Extra kW Information Fig 1 3 Surface Water Design Panel List 13 CHAPTER 1 Ground Loop Design Overview These seven panels include Results Fluid Soil Piping Surface Water Extra kW and Information The panel names and many of the panel input parameters differ from those of the Borehole Design module A more complete description about how to enter data and perform calculations in the Surface Water Design module is provided in Chapter 6 Theoretical Basis To determine the length of pipe necessary for different surface water systems experiments were conducted for different size pipes in coiled and slinky configurations for both heati
98. th the project file However ifthe associated loads file cannot be found the user will be notified and the automatic file loading will not occur 37 CHAPTER 4 The Borehole Design Module Saving Projects Projects may be saved at any time using Save or Save As from the Design Studio File menu or by clicking the save button on the toolbar When the user closes the program or module the program automatically asks the user if he or she wants to save the project and associated loads files Typical Operation Although each user will have his or her own unique style the typical operation of the Borehole Design module would include the following steps 1 Enter Loads and select pump s in the Zone Manager module 2 Forma link between the loads module and the design module 3 Modify step by step the input parameters listed in each panel 4 Perform initial calculation 5 Modify various parameters and recalculate to determine the effects of the modifications 6 Establish an optimal system 7 Save and or print the project and associated zone file Entering Data into the Tabbed Panels Ground Loop Design s innovative tabbed panel system provides for easy organization of and direct access to the relatively large number of design parameters associated with a particular project This section describes the Information Extra kW Pattern U Tube Soil Fluid and Results panels See Chapter 3 for a discussion of Loads entry I
99. the Dittus Boelter correlation for turbulent flow in a circular tube Incropera and DeWitt 1990 The calculations use average values of the Reynolds number to represent the different types of flow with values of Re 1600 3150 or 10000 for laminar transition and turbulent respectively The calculations also use average values of viscosity and the Prandtl number for water taken at a temperature of 70 F Using the standard expression for resistance of a hollow cylinder Incropera and DeWitt 1990 the program can calculate an approximate value for the pipe resistance It assumes HDPE pipe with a conductivity of 0 225 Btu h ft F The pipe resistance varies with the pipe style and flow The user can select the size and type of pipe from the appropriate selection boxes If another pipe diameter is required please contact support 43 CHAPTER 4 The Borehole Design Module Borehole Diameter and Backfill Grout Information The user can enter the borehole diameter and the grout thermal conductivity directly into their respective text boxes If cuttings are used for the backfill the average soil conductivity should be entered here Soil Input parameters relating to the soil are located in the Soil panel as shown in figure 4 6 These include the average ground temperature the soil thermal properties and the modeling time period F Borehole Design Project 1 Results Fluid Soil U Tube Pattern Extra kW Information
100. the design parameters have been established The Studio Link System The Studio Link system is a powerful feature in Ground Loop Design that gives users the ability to link or to unlink the loads module to or from the design modules When a loads module is linked to a Borehole Horizontal or Surface Water Design module all of the data in that loads module is transferred to the design module Once the connection is established the pertinent information is stored within the design module which makes transfers in from or out to the loads module as necessary Since the information is now held in the design module it is possible to add multiple design modules with only a single loads module open When studio links are established the information shown in the loads module will correspond to the active design project As long as a link is active design modules retain information about the type of link and the filename of the associated zone zon file This information is stored in saved project gld files so that the appropriate loads module can be opened and loaded when a project file is opened 3 Making a Link The most direct method of making a link between a loads and a design module is to open both modules to be linked activate click on the design module and then press the Link button on the toolbar Another option is to choose Link from the Ground Loop Design Loads menu Ifthere is only one type of loads module ope
101. the software is available in different languages it is truly international in its ability to traverse national borders as well as language and cultural barriers New in Residential Version 5 1 Ground Loop Design Residential Version 5 1 adds a range of features to the program including e fixed temperature and fixed length design modes in the borehole design module In fixed temperature mode designers specify inlet temperatures and the program calculates bore lengths In fixed length mode designers specify a loopfield length borehole length x number of boreholes and then have the program calculate heating and cooling inlet temperatures CHAPTER 1 Ground Loop Design Overview e Compatibility with the GeoXergy Plug In a program that offers loads calculations energy analysis and cost comparison cash flow payback and a greenhouse gas emissions reduction calculator See the GeoXergy Plug In documentation for more information The Design Studio The studio is the desktop work area in which the designer conducts his or her project analyses and establishes the basis for designs When additional projects are desired new windows may be opened or existing projects may be loaded The Loads module holds and displays the information for the particular installation Other windows may be opened concurrently For example one window may be used to design a vertical heat exchanger another design a horizontal heat exchanger and still others to provi
102. time Period In Ground Loop Design ten years is used as a standard length of time for the ground temperature to stabilize although longer time periods may be entered if desired When excessive ground water movement is known to occur one year is sometimes used as the modeling time period In this case it is assumed that the ground temperature stabilizes in a single year due to the neutralizing effects of the ground water movement For very shallow boreholes shorter modeling time periods may be used as well due to the neutralizing effects of the atmosphere Fluid The circulating fluid parameters may be entered in the Fluid panel A sample input screen is shown in figure 4 7 45 CHAPTER 4 The Borehole Design Module Design Heat Pump Inlet Fluid Temperatures The heat pump inlet fluid temperatures are included in the Fluid panel The designer can input the desired inlet source temperatures for both heating and cooling here When changes are made to these values the heat pumps in all zones are updated automatically Since the new calculated equipment capacities can lead to changes in selected equipment the designer must be aware of the changes Customized pump values must be manually adjusted A Note inlet temperatures can only be modified in fixed temperature mode Design System Flow Rate A The system flow rate per installed ton is included on the Fluid panel This is the system flow rate per ton of peak load not installed
103. ting one as an HTML file The easiest way to do this is to use an HTML editor It is much more difficult to make a table using plain HTML in a text editor Although any name is valid for a table tables can be added to the appropriate group by just extending the naming sequence already being 86 CHAPTER 8 Tables and Reference Files used For example the name PipeTable4 html could be used as the name for a new file Adding a Picture Graph or Figure If an image is stored as either jpg or gif it can be imported into an HTML page The HTML page can be linked directly to the Ground Loop Design reference files As an example let s assume that an engineer scans an image of his favorite density vs percent solute graph for Calcium Chloride and saves it in the Help Files directory as a jpeg image called CaCl2Density jpg A very simple HTML file can be created with a text editor and called FluidTable6 html The entire FluidTable6 html file would be as follows lt html gt lt head gt lt head gt lt body gt lt img SRC CaCl2Density jpg gt lt body gt lt html gt FluidTable6 html Remember the FluidTables html file would have to be edited to include the new link to the FluidTable6 html file similar to the example given in Editing Existing Files above If everything is done properly when Fluid Properties is selected from the Tables menu in the Design Studio Table 6 will appear as
104. tra kW Information Undisturbed Ground Temperature Ground Temperature 57 0 F Soil Thermal Properties Soil Type Average Rock y Ground Temperature Corrections at Given Depth Regional Air Temperature Swing 230 F Winter Summer Coldest Warmest Day in Year 34 225 Check Swing Temperature Table Fig 5 4 Soil Panel Contents Undisturbed Ground Temperature The undisturbed ground temperature refers to the temperature of the soil below the surface layer where there is no longer a seasonal swing This value may be determined from regional data or by recording the actual stabilized temperature of water circulated through pipe in a test bore Soil Thermal Properties The soil thermal properties thermal conductivity and thermal diffusivity are a little harder to define and care must be taken to select the correct soil type In the residential version of Ground Loop Design users can select the soil type that best matches the target installation soil environment The thermal conductivity in particular has a large effect on the calculated bore length and therefore soil type should be determined with care 57 CHAPTER 5 The Horizontal Design Module The following chart lists the conductivity and diffusivity values associated with each soil type option Soil Type Conductivity Diffusivity Btu h ft F ft day Light Soil Dry 0 20 0 26 Light Soil Damp 0 50 0 48 Hea
105. tton in the controls A dialog window appears giving the designer the list of available report styles After the making a choice click OK to bring up the report window There are five different zone reports included with Ground Loop Design Detailed Form Concise Form Equipment List Loads List Names List Detailed Form The Detailed Form zone report is the most detailed zone report It lists all of the information included in every zone along with full explanations of the listed parameters The format is open and easy to read However as with the project reports the detailed form produces a much longer printed report than any of the more compact versions 79 CHAPTER 7 Reports Concise Form The Concise Form zone report contains most of the detail of the long report but it is packed into a smaller space It does not include zone names occupation days detailed pump information manufacturer series and type or full descriptions of the items listed It does however contain important information about the loads and the operational parameters of the equipment matched to those loads Equipment List The Equipment List lists only the equipment associated with each zone It provides detailed pump information including name number manufacturer series and type plus all of the operational data associated with that pump It is an ideal report for engineers or contractors who require equipment lists but do not necessarily
106. ual Property Rights means patent rights including patent applications and disclosures copyrights including but not limited to rights in audiovisual works and moral rights trade secret rights rights of priority and any other intellectual property right recognized in any country or jurisdiction in the world Moral Rights means any right to claim authorship to or to object to any distortion mutilation or other modification or other derogatory action in relation to a work whether or not such would be prejudicial to the author s reputation and any similar right existing under common or statutory law or any country in the world or under any treaty regardless of whether or not such right is denominated or generally referred to as a moral right Confidential Information Customer agrees that Customer will not disclose or except as expressly permitted in this End User Agreement use any Software or other technical information disclosed to Customer by Gaia Confidential Information and that Customer will take all reasonable measures to maintain the confidentiality of all Confidential Information in Customer s possession or control which will in no event be less than the measures Customer uses to maintain the confidentiality of Customer s own information of equal importance Confidential Information will not include information that i is in or enters the public domain without breach of this End User Agreement ii Custom
107. ual number of circuits may be increased in the Piping panel to reduce the individual circuit lengths and thus reduce head losses However this type of reduction is not always necessary or desirable Other ways of increasing the maximum allowable number of parallel circuits include changing the system flow rate or the minimum circuit flow rate for non laminar flow The second section lists different temperature variables The first two of these are Source inlet and outlet temperatures The final variable is the approach temperature which is the difference between the pond temperature and the desired inlet source temperature Note In surface water heating applications although the solution within the pipe may not freeze the freezing temperature of the body of water is generally 32 F If the heat pump outlet temperature is too far below this value the water may 75 CHAPTER 6 The Surface Water Design Module freeze on the pipe greatly reducing its heat transfer characteristics and potentially leading to system failure The designer must always pay attention to the outlet temperature value for this reason As with the Borehole Design module the third section lists the total unit capacity the peak loads and the demand of all the equipment followed by the calculated heat pump and system efficiencies The peak load is the maximum determined from whichever time period across all the zones has the highest load The peak demand includes all
108. ule and the design module 3 Modify step by step the input parameters listed in each panel 4 Perform initial calculation 5 Modify various parameters and recalculate to determine the effects of the modifications 6 Establish an optimal system 7 Save and or print the project and associated zone file Before You Begin The theoretical model which is based on experimental data and non laminar flow requires a minimum system flow rate of 3 0 gpm ton in the pipes to achieve proper heat transfer Minimum flow rates through the circuit piping also are required to maintain the non laminar flow with different antifreeze solutions Thus there is a limit on the maximum recommended number of parallel circuits required in the system which in turn determines the length of an individual circuit Changing the pipe size requires a change in the minimum required flow rates which can either increase or decrease the maximum recommended number of parallel circuits and their lengths However this also can have substantial effects on the piping head losses which must also be considered in order to reduce the pumping costs To fully optimize a system in the Surface Water Design module the designer thoroughly must understand the relationship between the system flow rate the minimum required flow rates the pipe size the head loss per length of pipe and the preferred number of parallel circuits Ground Loop Design can conveniently make all the appropriate
109. vy Soil Dry 0 50 0 48 Heavy Soil Damp 0 75 0 60 Heavy Soil Saturated 1 40 0 84 Solid Masonry 0 75 0 60 Dense Concrete 1 00 0 79 Average Rock 1 40 0 96 Dense Rock 2 00 1 20 Ground Temperature Corrections at Given Depth In a horizontal configuration the ground temperature around buried pipes can vary significantly simply due to the proximity to the surface To account for this variation at different depths the regional Swing temperature and phase shift are used in a sinusoidal equation The program determines the depth of each pipe in the chosen configuration and then calculates the expected temperature at that depth Regional Air Temperature Swing This is the temperature swing for the location of interest It is a measure of the average temperature variation of the region during the warmest and coolest months as compared to the yearly average temperature Regions with temperate climates have a lower temperature swing than regions that have large differences between summer and winter temperatures Coldest Warmest Day in Year These are the actual days of the year on a 365 day scale when the temperature is usually coldest or warmest For example if February 3 is approximately the coldest day of the year the value entered will be 34 31 days in January plus 3 days of February 58 CHAPTER 5 The Horizontal Design Module Fluid The circulating fluid parameters may be entered in the Fluid panel A s
110. wed at any time on the Results panel After all data has been entered or any changes have been made the user can calculate interim or final results using the Calculate button A sample screen for the Results panel can be seen in figure 5 6 y Horizontal Design Project 2 Results Fluid Soil Piping Configuration Extra kW Information Calculate COOLING HEATING Total Trench Length ft 318 3 1000 1 Trench Number 5 5 Single Trench Length ft 63 7 200 0 Total Pipe Length A 636 7 2000 3 Single Trench Pipe Length ft 127 3 400 1 Unit Inlet F 85 0 45 0 Unit Outlet F 95 3 39 1 Total Unit Capacity kBtu Hr 48 4 44 2 Peak Load kBtu Hr 25 0 40 0 Peak Demand kW 2 8 3 8 Heat Pump EER COP 12 0 37 System EER COP 9 0 3 0 System Flow Rate gpm 6 3 10 0 Fig 5 6 Results Panel Contents The two lists on the Results panel are for heating and cooling Although all of the numbers shown are valid and respond to changes the side with the longer required length is printed in bold type so that it stands out The longer length determines the installation size and for this reason the shorter length system results lose relevance 61 CHAPTER 5 The Horizontal Design Module Reporting Section The reporting section is separated into several subsections The first deals with the trenches including the total length the number of trenches and the length for one trench A common way to adjust the trench l
111. with residential installations since the program can be used to design systems with peak loads of up to 200 kBtu hr Systems with larger peak loads often are characterized as commercial systems and generally require more advanced loads calculations to take into account both internal heat gains losses as well as long term thermal effects that determine the necessary design requirements For systems that are greater than 200 kBtu hr tons consider upgrading to our commercial ground loop design product which offers a wide range of additional and advanced design features as well as no limit on peak load tonnage The Residential Version of Ground Loop Design includes three design modules one for vertical borehole one for horizontal and one for surface water pond lake etc installations It also includes the Zone Manager loads module PREFACE Loads data can be shared between the loads module and the design modules enabling a designer to simultaneously compare and contract multiple heat exchanger designs using the same loads data In addition loads data from external loads programs the GeoXergy Plug In as well as from Excel files conveniently can be imported into the loads module With instant direct metric English unit conversions and foreign language capabilities Ground Loop Design is a truly international program With Ground Loop Design communicating project parameters equipment requirements and loads data with coworkers partners
112. ystems Click the Button in the Configuration panel for more information Trench Layout This is the section where the user enters all parameters regarding the physical size and placement of the trenches The number of trenches may be modified at any time using the up down arrows and Separation refers to the center to center distance between adjacent trenches The program assumes all trenches will be equal in separation length depth and width Note that if the selected piping configuration does not fit into the selected trench size the program will automatically adjust the size of the trench to accommodate the selection 52 CHAPTER 5 The Horizontal Design Module Horizontal Design Project 2 Results Fluid Soil Piping Configuration Extra kW Information Trench Layout 21 Number 5 Depth 12 0 ft Separation 10 0 ft Width 112 0 in Pipe Configuration in Trench DEI o te o a Total Number of Pipes 2 O O Vertical Separation Y 120 in k xt Horizontal Separation x 1120 in Fig 5 1 Configuration Panel Contents Pipe Configuration in Trench The designer defines the physical arrangement of pipe in the trenches in this section STRAIGHT PIPE CONFIGURATIONS In the case of the three straight pipe configurations the user also provides the total number of pipes and the horizontal X and vertical Y separation of the pipes in the trench An additional offset meaning a hori
113. zontal shift between adjacent vertical layers can be included if desired Single Pipe Vertical Alignment 53 CHAPTER 5 The Horizontal Design Module separation X Two Pipe Vertical Alignment In this arrangement the user creates two pipe layers number of pipes chosen defines how many layers will be included 2 4 6 etc Each vertical layer is separated from the one above or below by the given vertical separation Y If the Offset box is checked each pipe layer will be shifted from the pipe layer below by one half the given horizontal separation X 2 Three Pipe Vertical Alignment In this arrangement the user defines three pipe layers The number of pipes chosen defines how many layers will be included 3 6 9 etc Each vertical layer is separated from the one above or below by the given vertical separation Y If the Offset box is checked every layer will be shifted from the layer below by one half the given horizontal separation X 2 In this arrangement the user creates a single column of pipes The number of pipes chosen defines how many layers will be included Each pipe is separated from its neighbor by the given vertical separation Y starting from the bottom of the trench Ifthe Offset box is checked each pipe layer will be shifted from the pipe layer below by the given horizontal SLINKY PIPE CONFIGURATIONS In the case of the horizontal and vertical slinky configurati

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