Monday, 31 October 2022

Power factor correction/improvement

 

Power factor correction

Power factor basics:

Power quality is essential for efficient equipment operation, and power factor contributes to this.

Power factor is the measure of how efficiently incoming power is used in an electrical installation. It is the ratio of active to apparent power, when:

  • Active Power (P) = the power needed for useful work such as turning a lathe, providing light or pumping water, expressed in Watt or KiloWatt (kW)
  • Reactive Power (Q) = a measure of the stored energy reflected to the source which does not do any useful work, expressed in var or Kilovar (kVAR)
  • Apparent Power (S) = the vector sum of active and reactive power, expressed in Volt Amperes or in KiloVolt Amperes (kVA)
  • The power triangle:

    Poor power factor (for example, less than 95%) results in more current being required for the same amount of work.

    Power factor correction

    Power factor correction is obtained via the connection of capacitors which produce reactive energy in opposition to the energy absorbed by loads such as motors, locally close to the load. This improves the power factor from the point where the reactive power source is connected, preventing the unnecessary circulation of current in the network.

    Determining the power factor correction required

    • Calculation of the required reactive power

    1st step we have to determine the required reactive power (Qc (kvar)) to be installed to  improve power factor (cos φ) and reduces the apparent power (S).

    Qc can be determined from the formula Qc = P (tan φ – tan φ‘), which is deduced from the diagram.

  • Qc = power of the capacitor bank in kVAr
  • P = active power of the load in kW
  • tan φ = tangent of phase shift angle before compensation
  • tan φ’ = tangent of phase shift angle after compensation
  • The parameters φ and tan φ can be obtained from billing data, or from direct measurement in the installation.

    Step 2: Selection of the compensation mode

    The location of low-voltage capacitors in an installation can either be central (one location for the entire installation), by sector (section-by-section), at load level, or a combination of the latter two.

    In principle, the ideal compensation is applied at a point of consumption and at the level required at any moment in time. In practice, technical and economic factors govern the choice.

    The location is determined by:

  • the overall objective (avoiding penalties on reactive energy, relieving transformers or cables, avoiding voltage drops and sags)
  • the operating mode (stable or fluctuating loads)
  • the foreseeable influence of capacitors on the network characteristics
  • the installation cost
  • Step 3: Selection of the compensation type

    Different types of compensation should be adopted depending on the performance requirements and complexity of control:

  • Fixed, by connection of a fixed-value capacitor bank
  • Automatic, by connection of a different number of steps, allowing adjustment of the reactive energy to the required value
  • Dynamic, for compensation of highly fluctuating loads
  • Step 4: Allowance for operating conditions and harmonics

    Operating conditions have a great impact on the life expectancy of capacitors, so the following parameters should be taken into account:

  • Ambient temperature (°C)
  • Expected over-current related to voltage disturbances, including maximum sustained overvoltage
  • Maximum number of switching operations per year
  • Required life expectancy
  • Some loads (variable speed motors, static converters, welding machines, arc furnaces, fluorescent lamps, etc.) pollute the electrical network by reinjecting harmonics. It is therefore also necessary to consider the effects of these harmonics on the capacitors.

    The benefits of power factor correction

    Savings on the electricity bill

    Power factor correction eliminates penalties on reactive energy, decreases demand on kVA, and reduces power losses generated in the transformers and conductors of the installation.

    Increased available power

    Fitting PFC equipment on the low voltage side increases the power available at the secondary of a MV/LV transformer. A high power factor optimises an electrical installation by allowing better use of the components.

    Reduced installation size

    Installing PFC equipment allows conductor cross-section to be reduced, as less current is absorbed by the compensated installation for the same active power.

    Reduced voltage drops

    Installing capacitors allows voltage drops to be reduced upstream of the point where the PFC device is connected, therefore preventing overloading of the network and reducing harmonics.


    Why we connect Capacitor in parallel, not in series?



    Reason 1

    We know that in series connection Current is constant and voltage is varying but in parallel connection, voltage is constant and current is varying. 
    So we need to keep constant the voltage across the load. So if we connect a capacitor in parallel it will be drawn leading current according to its rated value. But if we connect a capacitor in parallel then the flow of current through the capacitor will depend on the load.


    Reason 2

    As in the case of series connection of capacitor current fully depends upon the load so we need a capacitor of high value which can deliver the full load current.


    Reason 3

    If we connect a capacitor in series with the load for power factor improvement then a voltage will be dropped by the capacitor.


    Reason 4

    If we connect the capacitor in series with the load then if short circuit fault occurs in the load then the total voltage will be applied to the capacitor which may blow them.


    Reason 5

    In case of series connection, if we want to connect additional capacitor then we need to open the whole circuit. But in case of parallel connection, we can easily connect an additional capacitor in parallel with the existing capacitor.


    Reason 6

    If we connect the capacitor in series with the load for power factor improvement then the recovery voltage across the contacts of the switchgear shall be high.

    No comments:

    Post a Comment

    TRANSISTORS

    TRANSISTORS A transistor is a semiconductor device that contains three regions separated by two distinct PN junctions. The two junctions are...

    Translate