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    INTERACTIVE POWER FACTOR COMPENSATION CHART & EXPECTED POWER FACTOR CONTROLLER PERFORMANCE

    The following webpage provides expected performance of power factor controllers that utilize proportional control algorithms for the control of single and multi-stage capacitor banks and harmonic filter banks. Required information includes: real power level of loads, the capacitor/filter bank stage rating in kvar, target power factor, and the dead band setting in percent within the controller.

    Various parameters are calculated to provide a full understanding of expected controller performance. Uneven inductive and capacitive dead band values can be examined to determine effect on controller performance.

    Note:

    1. Three-Phase Real Power of load to be compensated in KW.
    2. Power Factor of Load to be compensated.
    3. Target Power Factor of Load to be compensated. The target power factor is drawn as a linear line on the PQ diagram (see below).
    4. Three-Phase capacitor bank reactive power rating in kvar (the smallest step size in a multi-stage capacitor bank using binary step sizes).
    5. Inductive dead band width – the inductive level or "neutral zone" where no switching action occurs (the controller will not switch in this zone). The dead band prevents oscillation or repeated activation-deactivation cycles (called "hunting" in proportional control systems). The width of the inductive dead band is defined as a percentage of the capacitor step size.
    6. Capacitive dead band width – the capacitive level or "neutral zone" where no switching action occurs (the controller will not switch in this zone).
    7. Dead band width - equal to the sum of the capacitive and inductive dead band values. Usually a value near 150% is recommended.
    8. Reactive power level before compensation.
    9. Inductive switching level - required reactive power level required for a capacitor stage to be switched on (green line in graph below).
    10. Target reactive power level (black line in graph below) based on present power factor and real power level.
    11. Capacitive switching level - required reactive power level required for a capacitor stage to be switched off (red line in graph below).
    12. Expected controller action based on data provided.
    13. Reactive power required to meet target power factor – Difference between the present reactive power level and the target reactive power level. A negative value indicates leading vars.
    14. Total power of load before power factor correction.
    15. Total power of load at target power factor.
    16. Total power reduction as a result of applying power factor correction.
    17. Power factor at inductive switching level based on present real power level.
    18. Power factor at capacitive switching level based on present real power level.
    19. Line-to-line system voltage. Value is used to calculate C/K ratio (commonly referred to as response value) for power factor controller setup.
    20. CT (current transformer) ratio used to calculate C/K ratio for power factor controller setup.
    21. Inductive response value (C/K ratio) defines the inductive switching level in current transformer secondary amps based on the capacitor stage size, CT ratio, dead band width, and system voltage.
    22. Capacitive response value (C/K ratio) defines the capacitive switching level in current transformer secondary amps based on the capacitor stage size, CT ratio, dead band width, and system voltage.


    See Note                    
    1 Input Real Power of Load to be compensated (KW):   
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    2 Input Present Power Factor of above load:  
    3 Input Target Power Factor (use negative value for leading):  
    4 Input Step Size of Capacitor Bank (kvar):  
    5 Input Inductive Dead Band Width (%):  
    6 Input Capacitive Dead Band Width (%):  
           
    7 Dead Band Width (%):  
                          
    8 Reactive Power level before compensation (kvar):     
                         
    9 Inductive Switching Level (kvar):     
    10 Target Reactive Power Level (kvar):  
    11 Capacitive Switching Level (kvar):  
           
    12 Expected Controller Action:  
              
    13 Required Reactive Power Compensation to meet target (KVAR):   (mouse over graph to see values)  
           
    14 Initial Load kVA - Before PF Correction:                
    15 Compensated Load KVA at target power (KVA):    
    16 Released KVA at target power factor (KVA):    
             
    17 Power Factor at Inductive Switching Level:    
    18 Power Factor at Capacitive Switching Level:    
             
    19 Input System Voltage (VLL):              
    20 Input CT Ratio:   For example a 1200/5 CT has a ratio of 240    
    21 Inductive Response Valule (C/K Ratio):   IND Resp Value to Enter into NC12 Controller    
    22 Capacitive Response Valule (C/K Ratio):   CAP Resp Value to Enter into NC12 Controller    
                         
            kW Target step up step down      
              Target Power Factor On Value Off Value Present kvar Level  
            0    
               
            2000    
            3000    
            4000    
            5000    
            6000    
            7000    
            8000    
            9000    
            10000