RIDE THROUGH TECHNOLOGY
Contents
1. the torque drops by the square root Likewise if the voltage rises the available torque goes up by the square If the torque reduces due to a loss in voltage and the power demand remains the same the current goes up As the current goes up the voltage reduces This loop continues and the speed reduces until there is insufficient torque to rotate the shaft and the curve rises from minimum torque to locked rotor torque where the current goes to the locked rotor value Figure 4 Loss of rotation Breakdown Slip torque Cmx S Oe Normal running position Locked rotor f torque Cp ye 4 z pa N i a 4 Pa O j j Minimum torque Cmin Full load torque Ca Rated speed No H Speed Ns Figure 4 Typical torque speed curve for an induction motor 153 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 Motors should be selected for their required characteristics but normally a general purpose motor will be used Figure 5 300 909 __ X N 100 50 Torque as porcentage of full load torque 10 20 30 40 50 60 70 80 90 100 7a Speed Figure 5 Torque speed curves specific design 4 In Figure 5 the design characteristics for specific requirements can be seen Design N is the regular motor design where standard torque values are required It has low slip and is used on pumps machine tools fans and the like Design H has a high locked r2. these must be on UPS at that voltage as well There is sufficient intelligence within the relay that once you have programmed the motor nominal data into it it understands the parameters of the motor When setting the ride through duration it is able to make small compensations for the initial inrush current which may prevent tripping The UMC is intelligent enough to disable any protection functions such as low voltage low power factor but conflicts in setup need to be checked for It can be programmed to restart within a specific time period if required This can be used on remote unmanned pump stations Method 3 Soft starters The WEG SSW0O6 soft starter is used for this example Figure 6 The parameters required are P600 Immediate undervoltage P601 Immediate undervoltage time P610 Phase loss or immediate undercurrent In of the motor P611 Immediate undercurrent time or phase loss P616 Undercurrent before bypass closing P630 Time interval after stopping Can be used as a safety function P206 Auto Reset Time Initiate restart after power has been restored This function can be used on remote pump stations Warning The P206 function is dangerous and a Risk Analysis needs to be conducted Sufficient training is required and signage must be put in place 155 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 0 tis Figure 6 WEG SSW06 actuation levels for undervoltage and overvol
3. of ride through Firstly the power ride through where the output current to the motor is maintained and secondly the logic ride through where the control circuit 1s kept active and ready to reconnect to the motor when the line power is restored Extended definition of ride through The following examples would be for standard contactor systems as well as for electronically driven systems as these examples are more outcome defined e Short duration where the motor keeps running e Longer duration where the motor comes to a stop and is automatically restarted after a delay e Long low voltage situation which triggers an error e Two dips within a short period of time Motor characteristics To correctly achieve the full ability of the ride through it is necessary to comprehend what the motor is capable of and what the limitations are The required torque output is defined by the load and the speed constraints The available voltage will then be the next required input Then look at the load and decide how to start it with the electrical and mechanical limitations Typically small loads can be started direct on line DOL but so can large loads that have a sufficiently stiff electrical supply with the ability of the load to handle a shock start Starting will require somewhere between 6 10 times full load current depending on the load and motor type The torque is proportional to the square of the voltage nominal so if the voltage drops
4. that is relevant This also covers a total black out see Figures 1 3 Indicative targets for the number of voltage dips per year Table B 1 Indicative targets for the number of voltage dips per year for each category of dip window see figure B 1 Network voltage range Number of voltage dips per year see note Se ae ee ees 66kvto 4skv amp w 73 Skvosam y a j s y as o yo ooo Guwosaw s o 0 fowessw 2 3 3 NOTE The network voltage is not necessarily the voltage at which the customer takes supply It may be the voltage of the network that feeds the point of common coupling Therefore the set of Z T S X and Y values applicable to a customer should be evaluated in each case taking account of the network configuration supplying that customer Figure 1 NRS 048 4 1999 Annexure B Dip characteristics Magnitude of voltage depression Decrease below nominal 0 20 10 Dip duration ms Figure 2 NRS 048 4 1999 Annexure B Dip characteristics V mT Nom High roar cr Oe Se pa Standards Dip magnitude x of g clared x Uo below nominal ee ee eee eee Dip duration User defined setpoints l Retained Voltage Interruption ee o M l R Time Figure 3 Graphic view of power dips 152 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 Defining ride through There are two types
5. Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 REFEREED PAPER RIDE THROUGH TECHNOLOGY SKINNER BA AND WARD G 1 Montgomery Road Mount Edgecombe 4300 South Africa 51 Island Circle River Horse Valley Business Estate Durban South Africa bskinner illovo co za GlenW zest co za Abstract The rigid grid and spare capacity that was available in sugar mills are now a thing of the past Many sugar mills are or shortly will be connected to a national grid and co generating to derive a secondary income stream The dips brownouts and disconnections blackouts with varying durations tend to blackout the factory with the resultant losses and stresses that go with the restart The ability to ride through on critical equipment such as boiler fans boiler feed water and fuel feeders becomes essential to any protection and control philosophy and needs to be part of any sustained plan of operation for a sugar cane mill Keywords variable speed drive VSD soft starter UMC ride through energy recovery Introduction Ride through requirements stem from the need to keep equipment running While trying to sustain the motion all safety aspects must be covered and no compromise is acceptable The method of sustaining the ride through depends on the method of starting Merely keeping a motor supply energised until the supply is restored to full value is not correct or safe The methods covered in this paper will be fr
6. drops to below a level where the motor can accept energy This prevents a sudden inrush if power is restored At T4 the DC bus is above the pre charge level and the drive resumes At a lower voltage the DC link will fault and the drive will trip This is indicated by the continued decay line to where it crosses the minimum DC bus line 156 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 Line Loss Fault Miamum ocos o oo TT Undervoltage Fau depending on Low Sus Faut T3 Ta te Figure 7 Pre charge The time period of the ride through is a function of the difference between the 100 DC bus V and The point where the drive goes into pre charge mode seen here as 85 V2 As the energy in Joules is in watt seconds and derived from the capacitance C and the square of the DC link voltage J C V V23 To extend this ride through time a battery backup can be added to the DC bus An alternative to this would be to utilise the large inertia load to generate power into its DC bus and link that bus to the critical drive bus The larger high inertia load is then used to drive the smaller more critical load as discussed in method 4B below Method 4B VSD power ride through Inertia driven ride through In this method the load must be from a high inertia load where the output of the drive can be used to ensure that the pre charge levels can be maintained for long durations and thus
7. ey AC Drives 2 IEC 61000 4 11 2005 Electromagnetic compatibility EMC Part 4 11 Testing and measurement techniques Voltage dips short interruptions and voltage variations immunity tests 3 ABB UMC manual UMC 100 FBP issue 05 2013 4 WEG Motors Specification of Electric Motors 5 Electrical Engineering Portal Impacts of Voltage Dips on Power Quality Problems 6 NRS 048 4 1999 Rational User Specification Electricity Supply Quality of supply Part 4 Application guidelines for utilities 7 WEG SSWO6 Soft Starter User s Manual Document 0899 5854 13 159
8. oltage onto the stator and when the power is restored the phasor difference in the voltages may result in currents as high as 12 16 times full load current FLC in the worst case 154 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 This system is best controlled with short duration brownouts of loss of 15 30 of nominal speed for durations of 300 to 500 milliseconds This is preferred as opposed to blackouts or total loss of power where the motor is freewheeling when the power is restored The duration is controlled with a high accuracy timer once the level of inertia and degradation rate of the motor shaft is ascertained This system is prone to tripping on restoration of the voltage to nominal levels This can be used on high speed conveying systems which take more than one second to come to a standstill Method 2 Use of universal motor controllers The universal motor controller UMC is an independent electronic control and protection system Less expensive models monitor only the current input while more expensive systems monitor the voltage and current and thus can define voltage conditions as well as the current With these two factors real active and reactive power can be calculated in addition to the power factor and low load conditions The device not only acts as a protection relay but control system too It is supplied by a 24V DC UPS supply If contactors of another voltage are used on larger power devices
9. om the most simplistic to advanced variable speed drive VSD control The full comprehension of the desired outcome and the limitations of how to achieve it must be considered For this paper we will confine the discussion to three phase induction motors Defining a dip There is a very technical description contained within the IEC 61000 4 11 2004 Edition 2 Voltage Dip a sudden reduction of the voltage at a particular point of an electricity supply system below a specified dip threshold followed by its recovery after a brief interval It continues in a 29 page document which is highly complex and may not meet the definition of what is happening in your plant A shortened definition is a Voltage dip is commonly defined as any low voltage event between 10 and 90 of the nominal RMS voltage lasting between 0 5 and 60 cycles For the definition within this paper this can be stated as the point at which the interruption takes effect on the electrical system to when the voltage recovers sufficiently to allow normal operation From the nominal voltage Un the voltage is lowered until the contactors drop out including soft starter or the drive becomes unstable The recovery point where the contactors can pull in again is the recovery point This is regardless of whether the driven 151 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 system is energised by an external power supply or not as it is the power side
10. otor torque with a low slip These are specific for high starting torque applications such as screens conveyors high inertia loads and crushers Design D is for high locked rotor torques and high slip above 5 These are specifically for applications such as eccentric presses and machines with periodic loads Starting curves When you attach a load to a motor it will behave according to the load With a fan or centrifugal pump the torque curve increases exponentially with speed as the blades move more and more mass With a conveyor the torque rises very steeply and then flat lines A centrifugal pump has very little inertia as the liquid acts as a brake With a fan particularly one with dampers that close a huge amount of inertia is present that could result in several tens of minutes to stop A conveyor stops within one or two seconds so the available inertia 1s very low and the time period very short Method 1 Keeping the contactor energised from a remote UPS system This is a power ride through where the control voltage is supplied via an independent power supply and when the supply to the starter is removed the contactor is kept closed The motor begins to lose speed until it may even be at standstill but the contactor remains energised The best case 1s where the motor is at standstill and when the power is restored the motor accelerates as if it were started direct on line DOL If the motor is still turning it generates its own v
11. tage As the soft starter has a standard input for a dedicated power supply no special additional cost 1s involved for this specific function The method involves keeping the by pass and main contactors energised for the duration of the programmed dip or blackout When the power resumes it is as if the DOL has had the contactor retained as in the first method Larger soft starters should be used 1 e de rating the soft start as the starting current with a full load could be very excessive and the settings may be required to be adjusted accordingly Warning The reasoning behind the soft starting requirement needs to be fully understood to ensure that the electrical supply and or the load can take the shock load of the restart The combined switch on current on multiple starters on a single supply may exceed the main breaker protection limitations and trip This may be overcome by varying some of the time duration parameters to cascade the starting Method 4A VSD with power ride through Capacitive storage In Figure 7 at T1 the power is lost to the drive Energy is stored in the capacitors and power is maintained to the motor utilising this energy but the voltage level drops quickly The logic ride through is invoked between T2 and T3 where the rate of decay is much less as the drive is not producing power to the motor At T3 the power is restored The bus voltage is maintained at a higher level in a pre charge method when the voltage
12. the required RMS output voltage but with some elevated voltage spikes The motor must be able to handle these spikes Then you could purchase a drive at a higher voltage 690v and control the output voltage 400v This would enable the DC bus to be operated from a higher voltage source to provide the voltage head room Method 5 VSD Logic ride through Here the drive logic is maintained even though the drive is not delivering an output As indicated in the Allan Bradley paper there may be limitations imposed by manufacturers where the legal compliance is required and by way of example the UL Underwriters Laboratory in the USA requires that the drive have less than 50 volts on any internal component within one minute of a power shut down This would limit the duration of this ride through if this drive was purchased The term flying start is used where voltage feedback is used to ascertain the speed and the value for the incoming voltage when the drive goes live again The use of an encoder will enhance this method and speed up the reconnection as the drive is not able to calculate speed from slip and generally will start at zero Hertz and work its way up until it finds the correct value This may take a few seconds This method is limited to about 85 of Un Run On Power Up is similar to the delay on start function of the UMC and is used when there are remote machines requiring a restart after coming to a complete standstill after a po
13. wer interruption Which Method to use It is critical that the control and protection philosophy be completed so that the entire process can be worked through and a full comprehension achieved before embarking on this road Starting with methods to stopping the load should be an initial point as once the ride through is achieved it is critical that the stopping method be established and verified Cost is always a critical consideration but the benefits should ensure the sale of the selected method to the management team If speed variation is not required and the power loss duration is less than a second DOL units can utilise the UPS supply with timers or a UMC controller can be considered If longer durations on DOL are required then a step up to a soft starter will be needed The best method is the VSD and then if the power loss durations are over 30 seconds the inertia method is the solution encoder may be necessary The final word is safety If this method is employed to sustain your factory full disclosure and training for everyone is required especially when the ride through exceeds 10 seconds or the auto start after stop is employed Persons who are active in the plant during power failures will not be expecting motors to accelerate away or automatically start when this has not happened in the history of the plant before 158 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 BIBLIOGRAPHY 1 Allan Bradl
14. when the power is restored the drive computes the revolving flux into a speed and the drive accelerates away smoothly This is achieved by using the motor as an induction generator and reversing the current flow so it flows into the drive and charges the capacitor DC link Calculations on duration are more difficult as mass and inertia are required and the mechanical characteristics of the rotating mass may not be easy to come by especially in older plants Trials should be conducted and during these trials the best duration can be decided upon There are methods to extend the ride through time and even cope with single phasing that dips below the 50 level A separate boost converter can be used to supply the DC bus from an independent power source such as a UPS Another way is by the use of an active front end where the input power bridge which now looks like the output bridge is used to draw more current as the voltage drops This will be a further drain on the power supply and must be catered for in the design and the risk benefit should be fully considered A 25 drop in voltage will be accompanied by a 33 increase in current This cost can be quite considerable 157 Skinner BA and Ward G Proc S Afr Sug Technol Ass 2015 88 151 159 The Voltage Head Room method is a less expensive alternative to the above variation The drive bus can be set up for the lower voltage from the high voltage drive but the drive will still produce
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