1.practical for Energy Conservation Technique for Diploma electrical engineering.

AIM: STUDY OF POWER FACTOR IMPROVEMENT.

Objective: after studying this experiment, it will be possible to;

            (1) Identify the disadvantage of low power factor.

            (2) Identify the causes of low power factor

            (3) Mechanism of power factor correction improvement

Significance:-Machines and devices with inductive property forms the considerable part of energy considerable part of energy consumption system. Due to the inherent property of inductor the current always lags behinds voltage with reference to time and thus the total amount of electrical energy produced is divided into two sectionsL1) Real power : the main function desired from the device (2) Reactive Power: the power necessary for the functioning of the device. The ratio of such division is governed by the important parameter named as power factor and is a versatile master key for unlocking the many of our power systems problems.

Theory:

            Technically, the power factor is defined as cosine of angle between voltage vector and current vector of a.c. circuits. It is represented diagrammatically as shown in figure-1. It can also be derived from other relations as shown in figure-2 and figure-3.

Disadvantages of low power factor: As mentioned previously, majority of inductive devices present in the system results into low power factoe which leads to one or more of the following disadvantages:

1.      Large KVA rating of equipment

2.      Greater conductor size in transmission, distribution and consumer systems.

3.      Large copper loss

4.      Poor voltage regulation

5.      Reduction handling capacity of the system.

Thus low power factor is an objectionable feature in the supply system as well as form economical point of view.

Causes of low power factor:  Normally the power factor of the load on the supply system is lower than 0.8 lag. Following are the causes of low power factor.

1.      Induction motor works at a power factor which is extremely small on light load (0.2 to 0.3) and rises to 0.8 to 0.9 at full load.

2.      Arc lamps, electric discharge lamps and industrial heat furnaces operate at low lagging power factor.

3.      The load on the power system is varying: being high during morning and evening and low at other time. During low load periods, supply voltage is increased which increases the magnetization current. This results in the decreased power factor.

Power factor improvement:  So, to eliminate the causes and improve the power factor, we desperately require to consider the property of the elements which is compensative in nature. Capacitor is one of each element in which the current leads the applied voltage and this property can be utilized to improve the power factor. The same thing is illustrated diagrammatically in figure-4.

            As shown in the figure, due to the capacitive effect the charging current flows ahead of voltage vector and resultant current drawn from supply is brought to II and from ф₁ to ф_2. Thus improving the power factor.

Elements utilized in power factor improvement: The following equipment can be utilized for power factor improvement.

1.      Static capacitors

2.      Synchronous condensers

3.      Phase advancers

Calculation of power factor correction: With the of power factor triangle, the power factor improvement can be calculated in terms of leading KVAR supplied by power factor correction improvement.

As shown in figure-5,

KVAR₁=KVAR₂=KVAR_c

Therefore,

KVAR_c = KVAR₁ + KVAR₂  

Where KVAR_c = Leading KVAR supplied by power factor correction improvement. If we divide the main triangle into two subordinate right angle triangles, we can have the following relationship of KVAR from the basic rules:

1.      KVAR₁/KW = tan ф₁ i.e. KVAR₁ = KW tanф₁

2.      KVAR₂/KW = tanф₂ i.e. KVAR₂ = KW tanф₂  

Utilizing these results for equation (a) we get,

KVAR_c  = KW tanф₁ - KW tanф₂

Therefore,

KVAR_c = KW(tanф₁ -  tanф₂ )

This is an important relation to find out the leading KVAR_c supplied by power factor correction improvement.

As power factor improvement is intended for reducing maximum demand and also decreasing the tariff rate on KWH, it also incurs the capital the cost of p.f. improving equipment in terms of rate interest and depreciation. The net saving is also affected by all such factors. Therefore,

The value to which the power factor should be improved so as to have maximum net annual saving is known as the MOST ECONOMICAL POWER FACTOR.

Importance of power factor improvement:

It is desired below for both consumers and generating stations.

(i)    Consumers: A consumer has to pay less electricity charges for his maximum demand in KVA plus the units consumed.

(ii)  Generating Stations: Number of units supplied by it depends upon the power factor. Greater the p.f. of generating stations, higher the KWH it delivers to the system. This is according to the formula, KW = KVAcosф

Suppose if we consider the following parameters for power factor improvement, P- Peak load in KW taken by consumer at p.f. cosф, rate is x Rs. Per KVA maximum demand per annum, cosф₂ is improved p.f. due to p.f. improving equipment, y Rs. Is expenditure incurred on p.f. improving equipment per KVAR per annum then,

Most economical p.f.

 cosф₂ = square root of (1-(y/x)2).

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