INSTRUCTION MANUAL FOR VAR/POWER FACTOR CONTROLLER SCP

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INSTRUCTION MANUAL FOR VAR/POWER FACTOR CONTROLLER SCP 250 Publication: 9 1100 00 99Y Revision: S 04/04

INTRODUCTION This instruction manual provides information about the operation and installation of the SCP 250 Var/Power Factor Controller. To accomplish this, the following information is provided. General Information and Specifications Control Descriptions Functional Description Installation Drawings Operating Procedures WARNING! To avoid personal injury or equipment damage, only qualified personnel should perform the procedures in this manual. CAUTION The use of high potential test equipment will damage SCP 250 circuitry. SCP 250 Introduction i

First Printing: November 1984 Printed in USA Copyright 2004 Basler Electric, Highland Illinois, USA April 2004 CONFIDENTIAL INFORMATION of Basler Electric, Highland Illinois, USA. It is loaned for confidential use, subject to return on request, and with the mutual understanding that it will not be used in any manner detrimental to the interest of Basler Electric. It is not the intention of this manual to cover all details and variations in equipment, nor does this manual provide data for every possible contingency regarding installation or operation. The availability and design of all features and options are subject to modification without notice. Should further information be required, contact Basler Electric. BASLER ELECTRIC ROUTE 143, BOX 269 HIGHLAND IL 62249 USA http://www.basler.com, info@basler.com PHONE +1 618.654.2341 FAX +1 618.654.2351 ii Introduction SCP 250

CONTENTS SECTION 1 GENERAL INFORMATION... 1-1 INTRODUCTION... 1-1 FEATURES... 1-1 APPLICATION... 1-1 Generator Peaking Application (SCP 250-G)... 1-1 Synchronous Motor Application (SCP 250-M)... 1-1 Isolated Bus Applications... 1-2 PART NUMBERS... 1-2 SPECIFICATIONS... 1-2 Voltage Sensing and Input Power... 1-2 Current Sensing... 1-2 Output Signal... 1-2 Enable Contact... 1-2 Control Accuracy... 1-2 Type Tests... 1-3 Operating Temperature... 1-3 Weight... 1-3 SECTION 2 CONTROLS... 2-1 CONTROLS ILLUSTRATION AND DESCRIPTION... 2-1 SECTION 3 FUNCTIONAL DESCRIPTION... 3-1 INTRODUCTION... 3-1 INPUTS... 3-1 COMPARATOR AND ERROR AMPLIFIER... 3-1 VOLTAGE LIMITING... 3-2 CONTROL RELAY... 3-2 SECTION 4 INSTALLATION...4-1 GENERAL... 4-1 MOUNTING... 4-1 CONNECTIONS... 4-3 Interconnection Diagrams... 4-3 Remote Control of the SCP 250... 4-19 SECTION 5 OPERATION... 5-1 INTRODUCTION... 5-1 GENERATOR APPLICATIONS... 5-1 Preliminary Adjustments for Var Control...5-1 Preliminary Adjustments for Power Factor Control... 5-2 MOTOR APPLICATIONS... 5-3 Preliminary Adjustments for Power Factor Control... 5-3 Figures Figure 2-1. SCP 250 Controls... 2-1 Figure 3-1. SCP 250 Function Block Diagram... 3-1 Figure 4-1. SCP 250 Outline and Drilling Dimensions... 4-2 Figure 4-2. AVC63-12/AVC-125-10 and SCP 250-G Connections... 4-4 Figure 4-3. KR-F/KR-FF and SCP 250-G Connections... 4-5 Figure 4-4. KR-F/KR-FF and SCP 250-M Connections... 4-6 Figure 4-5. MVC 236, RA-70, AND SCP 250-M Connections... 4-7 Figure 4-6. SR-A and SCP 250-G Connections... 4-8 Figure 4-7. SR-A and SCP 250-M Connections... 4-9 Figure 4-8. SR-E/SR-F/SR-H and SCP 250-G Connections... 4-10 Figure 4-9. SR-E/SR-F/SR-H and SCP 250-M Connections... 4-11 Figure 4-10. SSE and SCP 250-G Connections... 4-12 Figure 4-11. SSE and SCP 250-M Connections... 4-13 Figure 4-12. SSR and SCP 250-G Connections... 4-14 SCP 250 Introduction iii

Figure 4-13. XR2001/XR2001F and SCP 250-G Connections... 4-15 Figure 4-14. XR2001/XR2001F, SPM 2000, and SCP 250-G Connections... 4-16 Figure 4-15. XR2002/XR2002F and SCP 250-G Connections... 4-17 Figure 4-16. XR2003/XR2003F and SCP 250-G Connections... 4-18 Figure 4-17. Potentiometer and Switch Connections... 4-19 Figure 5-1. Power Factor Relationships... 5-1 Tables Table 1-1. SCP 250 Part Numbers... 1-2 Table 2-1. Description of SCP 250 Controls... 2-1 Table 4-1. SCP 250 Interconnection Diagrams... 4-3 iv Introduction SCP 250

SECTION 1 GENERAL INFORMATION INTRODUCTION The SCP 250 controls generator (SCP 250-G) or motor (SCP 250-M) power factor or vars by monitoring the voltage and current and supplying a control input to a voltage regulator. When the SCP 250 is controlling vars, the voltage regulator (or static exciter) output changes to attain the selected reactive load current. When the SCP 250 is controlling power factor, the voltage regulator adjusts the excitation until the selected power factor is obtained. The SCP 250 monitors the open/closed state of the circuit breaker so that the voltage regulator controls excitation when the breaker is open and the SCP 250 controls excitation when the breaker is closed. A voltage limiting feature in the SCP 250 prevents the voltage regulator from supplying full or no excitation if utility power is lost and the peaking generator main breaker remains closed. Voltage limiting is adjustable between ±10% and ±30%. Because the SCP 250 is designed for behind-the-panel mounting, provisions are included for locating the Var/PF switch and potentiometer remotely. FEATURES SCP 250 Var/Power Factor Controllers have the following features. Suitable for use in generator or synchronous motor applications Provide system control over a wide range of loading conditions Accommodate standard voltage sensing inputs Front panel selection of either var or power factor control Do not require use of motor operated control Specifically designed to operate with the standard Basler SR, KR, selected AVCs, SSR regulator series, and SSE static exciter-regulators During power factor control, reactive load changes automatically when kw load is changed Easily calibrated on site UL recognized and CSA certified APPLICATION The SCP 250 is suitable for use in generator peaking and synchronous motor applications. Generator Peaking Application (SCP 250-G) In peaking generator applications, the paralleling circuit of a voltage regulator presents large changes in reactive current when the bus voltage changes by a relatively small amount. However, the regulator s ability to compensate for large changes in bus voltage can be exceeded. Two examples illustrate typical problem areas. Example 1. A generator equipped with a voltage regulator adjusted for 4% droop can have a variation in var load from zero to 100% with a 4% decrease in bus voltage. Further decreases in bus voltage would overload the generator. Example 2. An increase in bus voltage can cause leading power factor conditions with the associated danger of the machine pulling out of synchronization. To minimize the possibility of either example occurring, the SCP 250 is used and adjusted for operation in a safe region with either a regulated fixed var level or a fixed power factor. Thus, for a large change in reactive current due to bus voltage changes, the operating generator is unaffected. Synchronous Motor Application (SCP 250-M) In synchronous motor applications, the SCP 250 allows the desired operating power factor to be preprogrammed so that the motor power factor remains constant during normal loading conditions. During transient loading conditions, the SCP 250 makes corrective motor field excitation adjustments through a regulator or exciter-regulator and thereby minimizes the possibility of synchronous pullout. SCP 250 General Information 1-1

CAUTION The SCP 250 should not be put into operation until after the motor is up to rated speed and the field is excited. Isolated Bus Applications The SCP 250 is not intended for use on isolated bus systems (systems providing power independent of a larger power source, such as a utility). In an isolated bus system using precise voltage regulators with parallel compensation, the var load is automatically divided between the generators by the regulator and its associated paralleling circuit. PART NUMBERS Table 1-1 lists the model numbers, part numbers, and application information for standard-order SCP 250 controllers. Table 1-1. SCP 250 Part Numbers Model Number Part Number Application SCP 250-G-60 9 1100 00 109 60 Hz generators SCP 250-G-50 9 1100 00 110 50 Hz generators SCP 250-M-60 9 1100 00 111 60 Hz motors SCP 250-M-50 9 1100 00 112 50 Hz motors SPECIFICATIONS SCP 250 electrical and physical specifications are listed in the following paragraphs. Voltage Sensing and Input Power 60 Hz Voltage Range: 120 to 139 Vac, 208 to 240 Vac, 416 to 480 Vac, 520 to 600 Vac, ±10% 50 Hz Voltage Range: 100 to 120 Vac, 190 to 208 Vac, 380 to 415 Vac, 440 to 500 Vac, ±10% Configuration: Single-phase Common Terminal: E1 Current Sensing Nominal Rating: 3 to 5 Aac 15 Second Rating: 30 Aac Configuration: Single-phase Burden: 3 VA Terminals: 1, 2 Output Signal Low Range: ±1 to ±3 Vdc (jumper installed at terminals X and Y) High Range: ±1 to ±9 Vdc (jumper removed) Terminals: A, B, C Enable Contact Rating: Terminals: Control Accuracy Power Factor: Vars: 60 Vac, 39 ma J, K Reactive component of current is proportional to real component within ±5% of maximum rated current. Reactive component of current maintained at programmed level within ±5% of maximum rated current. 1-2 General Information SCP 250

Type Tests Vibration: Shock: Operating Temperature Range: Weight Net: Shipping: 2 G in each of three mutually perpendicular planes swept over the range of 10 to 500 Hz for a total of six sweeps, 15 minutes per sweep Withstands up to 15 G in each of three mutually perpendicular planes 40 to 70 C ( 40 to 158 F) 6.75 lb (3.06 kg) 8.0 lb (3.63 kg) SCP 250 General Information 1-3

SECTION 2 CONTROLS CONTROLS ILLUSTRATION AND DESCRIPTION SCP 250 controls are shown in Figure 2-1 and described in Table 2-1. Figure 2-1. SCP 250 Controls Locator A Table 2-1. Description of SCP 250 Controls Control Description Mode Switch. This switch selects between var and power factor control. When the mode switch is in the VAR position, the desired reactive power level is established with the Var/Power Factor Adjust control. The var level is then held constant and will not vary if changes in watt load occur. When the mode switch is in the Power Factor position, the desired power factor is established using the Var/Power Factor Adjust control. The power factor is held constant even if watt load varies. SCP 250 Controls 2-1

Locator B C D E Control Description Var/Power Factor Adjust Control. This control is used to establish the var level or power factor, depending on the position of the mode switch. The control has two sets of calibration marks one set for var control and one set for power factor control. The power factor calibration marks shown in Figure 2-1 are for an SCP 250-M and will differ from the power factor calibration marks on an SCP 250-G. VAR Range Control. This single-turn potentiometer calibrates the SCP 250 when the mode switch is the VAR position. Var calibration is described in Section 5, Operation. Output Limit Control. This single-turn potentiometer adjusts the control output of the SCP 250. The output is adjustable from approximately ±1 Vdc (fully counterclockwise) to approximately ±3 Vdc (fully clockwise) or ±9 Vdc (jumper removed from terminals X and Y). This causes a corresponding change in generator output voltage of about ±10% to ±30% when the generator is isolated from the bus. Balance Control. This single-turn potentiometer is ordinarily set at its midrange position. It can be adjusted to attain extra precision in the maintenance of power factor in peaking service over a wide range of kw loading. Use of the balance control is described in Section 5, Operation. 2-2 Controls SCP 250

SECTION 3 FUNCTIONAL DESCRIPTION INTRODUCTION SCP 250 functions are illustrated in Figure 3-1 and described in the following paragraphs. Figure 3-1. SCP 250 Function Block Diagram INPUTS The SCP 250 has two inputs: a voltage input and a current input. The SCP 250 measures the real and reactive power based on these two inputs. The voltage input also supplies operating power to the SCP 250 power supply. COMPARATOR AND ERROR AMPLIFIER When var control is selected, the reactive component is compared to an adjustable dc reference and the error signal from this comparison is amplified and supplied to the voltage regulator. As a result, the voltage regulator (or static exciter regulator) changes its output until the programmed reactive load current is attained. When power factor control is selected, the reactive component is compared with an adjustable sample of the real power component, which serves as a reference. The error signal from this comparison is amplified and supplied to the voltage regulator. The regulator responds by changing the excitation until the selected power factor is attained. SCP 250 Functional Description 3-1

VOLTAGE LIMITING The SCP 250 voltage limiter prevents the voltage regulator from supplying full or no excitation if utility power is lost and the generator main breaker remains closed. Voltage limiting is adjustable between ±10% and ±30%. CONTROL RELAY The control relay (K1) enables and disables the SCP 250 output and is controlled by the Enable Contact input (terminals J and K). The Enable Contact input is typically interconnected with external breaker auxiliary contacts (52b). When the external breaker is open (52b contacts closed), K1 energizes and its contacts short-circuit the SCP 250 output terminals together. This disables the SCP 250 output and gives the voltage regulator total control of generator excitation. When the external breaker is open (52b) contacts open), K1 de-energizes and enables the SCP 250 output. The SCP 250 control output is applied to the voltage regulator and the SCP 250 assumes a major portion of excitation control. 3-2 Functional Description SCP 250

SECTION 4 INSTALLATION GENERAL Upon receipt of an SCP 250, check the part number against the requisition and packing list for agreement. Inspect for damage, and if there is evidence of such, file a claim with the carrier and notify the Basler Electric regional sales office, your sales representative, or a sales representative at Basler Electric, Highland, Illinois. MOUNTING The SCP 250 is intended for back-of-the-panel mounting in any plane. It should not be installed in a location where ambient operating temperature exceeds the range of 40 to 70 C ( 40 to 158 F). SCP 250 dimensions are shown in Figure 4-1. All terminal screws are 6-32 on 0.375 inch (9.5 millimeter) centers. Drawing dimensions are shown in inches with millimeters in parenthesis. SCP 250 Installation 4-1

Figure 4-1. SCP 250 Outline and Drilling Dimensions 4-2 Installation SCP 250

CONNECTIONS SCP 250 connections will vary according to the application (generator or motor) and the type of voltage regulator used. The secondary voltage of the potential transformer used in an application determines which SCP 250 power connections are used. Input power (operating power and sensing voltage) is applied to terminal E1 and one of the following terminals: 120-139 Vac, 208-240 Vac, 416-480 Vac, or 520-600 Vac. CAUTION The use of high potential test equipment will damage SCP 250 circuitry. Interconnection Diagrams The SCP 250 should be connected using the appropriate interconnection diagram. Table 4-1 lists the interconnection diagrams for common applications using the SCP 250 and other Basler control devices. Table 4-1. SCP 250 Interconnection Diagrams Application Diagram AVC63-12/AVC125-10 voltage regulator and SCP 250-G Figure 4-2 KR-F/KR-FF voltage regulator and SCP 250-G Figure 4-3 KR-F/KR-FF voltage regulator and SCP 250-M Figure 4-4 MVC 236 manual voltage control, RA-70P reference adjuster, and SCP 250-M Figure 4-5 SR-A voltage regulator and SCP 250-G Figure 4-6 SR-A voltage regulator and SCP 250-M Figure 4-7 SR-E/SR-F/SR-H voltage regulator and SCP 250-G Figure 4-8 SR-E/SR-F/SR-H voltage regulator and SCP 250-M Figure 4-9 SSE control chassis and SCP 250-G Figure 4-10 SSE control chassis and SCP 250-M Figure 4-11 SSR voltage regulator and SCP 250-G Figure 4-12 XR2001/XR2001F voltage regulator and SCP 250-G Figure 4-13 XR2001/XR2001F voltage regulator, SCP 250-G, and three-phase sensing module Figure 4-14 XR2002/XR2002F voltage regulator and SCP 250-G Figure 4-15 XR2003/XR2003F voltage regulator and SCP 250-G Figure 4-16 SCP 250 Installation 4-3

GEN 5 A A B BUS FIELD + - C N USE TWISTED, SCHIELDED -TYPE CABLES X Y J K F1 AVC63-12 or AVC125-10 F2 5a 6 22 24 20 2 1 E1 E3 SCP250 S1 S2 S3 P1 P2 PF VAR 3 A B P3 5 kohms 2 C 1. 2. A-B-C ROTATION SHOWN. CONNECT VOLTAGE INPUT TO PROPER TAP TO MATCH GENERATOR OUTPUT VOLTAGE. P0009-24.vsd 06-18-01 Figure 4-2. AVC63-12/AVC125-10 and SCP-250-G Connections 4-4 Installation SCP 250

Figure 4-3. KR-F/KR-FF and SCP 250-G Connections SCP 250 Installation 4-5

Figure 4-4. KR-F/KR-FF and SCP 250-M Connections 4-6 Installation SCP 250

Figure 4-5. MVC 236, RA-70, and SCP 250-M Connections SCP 250 Installation 4-7

Figure 4-6. SR-A and SCP 250-G Connections 4-8 Installation SCP 250

Figure 4-7. SR-A and SCP 250-M Connections SCP 250 Installation 4-9

Figure 4-8. SR-E/SR-F/SR-H and SCP 250-G Connections 4-10 Installation SCP 250

Figure 4-9. SR-E/SR-F/SR-H and SCP 250-M Connections SCP 250 Installation 4-11

Figure 4-10. SSE and SCP 250-G Connections 4-12 Installation SCP 250

Figure 4-11. SSE and SCP 250-M Connections SCP 250 Installation 4-13

Figure 4-12. SSR and SCP 250-G Connections 4-14 Installation SCP 250

Figure 4-13. XR2001/XR2001F and SCP 250-G Connections SCP 250 Installation 4-15

Figure 4-14. XR2001/XR2001F, SPM 2000, and SCP 250-G Connections 4-16 Installation SCP 250

Figure 4-15. XR2002/XR2002F and SCP 250-G Connections SCP 250 Installation 4-17

Figure 4-16. XR2003/XR2003F and SCP 250-G Connections 4-18 Installation SCP 250

Remote Control of the SCP 250 If desired, the Var/Power Factor Adjust control and Mode switch can be relocated away from the SCP 250. To relocate the potentiometer and switch, perform the following steps. If only one of the controls is to be relocated, perform only the instructions pertaining to the control to be removed. If user-supplied controls will be used, the controls installed on the SCP 250 chassis may be left in place. However, the controls must be disconnected from the SCP 250 by unsoldering and removing the control leads or taping the lead ends. 1. Gain access to the potentiometer and switch connections by removing the five screws that secure the circuit board to the chassis. 2. Disconnect the potentiometer and/or switch leads from the SCP 250 terminals. 3. Remove the potentiometer and/or switch from the chassis. 4. Secure the circuit board to the chassis with the five screws removed in step 1. 5. Unsolder and remove the leads from the potentiometer and/or switch. 6. Mount the potentiometer and/or switch in the desired location. 7. Connect wires from the potentiometer and/or switch to the SCP 250 terminals. Figure 4-17 illustrates the potentiometer and switch connections to the SCP 250. Figure 4-17. Potentiometer and Switch Connections SCP 250 Installation 4-19

SECTION 5 OPERATION INTRODUCTION The graph of Figure 5-1 illustrates the relationship between power factor and the corresponding ratios of reactive power to real power in an ac system. For example, in a 0.8 power factor load, reactive power is 75% of real power. This graph can be useful when adjusting the SCP 250 and evaluating system performance. This is particularly true when a varmeter and wattmeter are available but a power factor meter is not available. Figure 5-1. Power Factor Relationships GENERATOR APPLICATIONS The following procedures contain instructions for preliminary adjustment of the SCP 250 in generator applications. Preliminary Adjustments for Var Control 1. Rotate the Output Limit control fully counterclockwise. 2. Place the Mode switch in the VAR position. 3. Adjust the Balance control to the midrange position. 4. Rotate the VAR Range control fully counterclockwise. 5. Connect a jumper across terminals J and K. 6. Start the generator and set its voltage at nominal with the voltage regulator s voltage adjust control. NOTE With the 52 breaker open, voltage drift may be observed. This drift will disappear when the breaker is closed in step 12. SCP 250 Operation 5-1

7. Remove the jumper from terminals J and K. 8. Vary the Var/Power Factor Adjust control from one end of its range to the other. The generator voltage will vary between 10% above nominal to 10% below nominal. When the Output Limit control is turned clockwise, the variation of generator voltage is extended. 9. Set the Output Limit control for the variation that corresponds to about 5% more than the worst-case fluctuation of bus voltage. If the Output Limit control is set for too narrow a band, the SCP 250 may not provide control if bus voltage variation exceeds the percentage established by the Output Limit control. 10. Position the Var/Power Factor Adjust control at the 0 var position. 11. Connect a jumper across terminals J and K. (If the SCP 250 is connected according to the interconnection diagrams in Section 4, these terminals should already be shorted by the breaker s 52b auxiliary contacts.) 12. Parallel the generator with the bus using conventional procedures. The SCP 250 J to K connection should now be open (52b contact open). If the SCP 250 is operating properly and system interconnection is correct, there should be zero var flow. 13. Rotate the Var/Power Factor Adjust control clockwise. Vars should gradually increase but should be less than rated. 14. Slowly rotate the Var/Power Factor Adjust control clockwise until the generator is delivering rated kvars, as determined using system instrumentation. Control of var flow (absorb/generate) is now obtained directly using the Var/Power Factor Adjust control. Preliminary Adjustments for Power Factor Control 1. Rotate the Output Limit control fully counterclockwise. 2. Place the Mode switch in the VAR position. 3. Adjust the Balance control to the midrange position. 4. Connect a jumper across terminals J and K. 5. Start the generator and set its voltage at nominal with the voltage regulator s voltage adjust control. 6. Remove the jumper from terminals J and K. NOTE With the 52 breaker open, voltage drift may be observed. This drift will disappear when the breaker is closed in step 12. 7. Vary the Var/Power Factor Adjust control from one end of its range to the other. The generator voltage will vary between 10% above nominal to 10% below nominal. When the Output Limit control is turned clockwise, the variation of generator voltage is extended. 8. Set the Output Limit control for the variation that corresponds to about 5% more than the worst-case fluctuation of bus voltage. If the Output Limit control is set for too narrow a band, the SCP 250 may not provide control if bus voltage variation exceeds the percentage established by the Output Limit control. 9. Place the Mode switch in the Power Factor position. 10. Position the Var/Power Factor Adjust control at the 1.0 power factor position. 11. Connect a jumper across terminals J and K. (If the SCP 250 is connected according to the interconnection diagrams in Section 4, these terminals should already be shorted by the breaker s 52b auxiliary contacts.) 12. Parallel the generator with the bus using conventional procedures. The SCP 250 J to K connection should now be open (52b contact open). 13. Adjust the Var/Power Factor Adjust control to the desired power factor. 14. Vary kw loading from no load to maximum load. At maximum load, compare the power factor as indicated on the system power factor meter with the desired power factor set in step 13. If they are not identical, adjust the Var/Power Factor Adjust control until the power factor meter displays the 5-2 Operation SCP 250

desired power factor. Decrease the kw load to a minimum value. The desired power factor should be maintained over the entire range of loading. In the event that power factor is not maintained at low loading, perform the following steps. a) Reduce kw loading to about 20% of rated load. b) Adjust the Balance control until the system instrumentation indicates the desired power factor has been obtained. MOTOR APPLICATIONS The following procedures contain instructions for preliminary adjustment of the SCP 250 in motor applications. CAUTION Avoid establishing a lagging power factor so low as to cause the motor to pull out of synchronization. Avoid establishing a leading power factor so high as to cause field overheating. Appropriate protective devices should be considered to remove field excitation in the event a pull-out condition occurs. Preliminary Adjustments for Power Factor Control 1. Adjust the Balance control to the midrange position. 2. Adjust the VAR Range control to the midrange position. 3. Adjust the Output Limit control to the midrange position. 4. Place the Mode switch in the Power Factor position and adjust the Var/Power Factor Adjust control to the desired power factor. 5. Connect a jumper across terminals J and K. 6. Start the motor. 7. Vary the voltage regulator s voltage adjust control until the motor power factor is at the desired value. 8. Remove the jumper from terminals J and K. Carefully monitor field current and/or voltage to assure proper phasing. Control of power factor is now directly obtained using the Var/Power Factor Adjust control. SCP 250 Operation 5-3