CN1651925A - Method for metering transformer loss - Google Patents

Abstract

The present invention discloses a transformer power consumption metering method in power industry and metallurgical industry. Said method includes the following steps: according to the real-time dynamic data of actually-measured transformer primary and secondary active power P, reactive Q, total power S and power factor COS phi substracting secondary electric quantity data from same moment primary electric quantity data so as to obtain actual generated value of transformer electric quantity consumption, dividing correspondent primary data by said value and calculating unit consumption rate of every electric quantity parameter, according to the calculated result creating dynamic data base of every parameter by transformer energy-saving management software calculating minimum value of every parameter when the transformer is in economic running state, after the difference value exceeds a certain range, outputting control or alarm signal so as to implement real-time control of transformer consumption.

Description

Method for metering transformer loss

Technical field

The present invention relates to be applied to power industry, metallurgy industry transformer efficiency loss metering method.

Background technology

Transformer is as the major equipment of Operation of Electric Systems, and in the process of voltage of transformation and transmitted power, self will produce power attenuation.The power attenuation of transformer is relevant with the technical characteristic of transformer, produce simultaneously nonlinear variation again along with the variation of load, the large percentage that the line loss of the loss of transformer in electrical network is shared, according to statistics, electric energy will lose about 10% by transformer and transmission line of electricity, and transformer loss accounts for 6%, 1 year about 47,000,000,000 kilowatt hour of the energy loss on transformer of China, can transformer economical operation, the benefit that is related to enterprise, seek a kind of loss of scientific and feasible method calculating transformer, and control in real time makes its economical operation to energy-saving and cost-reducing significant.

The transformer efficiency loss divides two parts, and the loss irrelevant with load is called open circuit loss, with the load loss that is called of load variations.Open circuit loss Δ S ₀Expression, calculating formula is as follows:

${\mathrm{\ΔS}}_0={\mathrm{\ΔP}}_0+j\frac{I_0\%}{100}S$

Load loss claims short circuit loss again, refers to the loss in the Transformer Winding, and it is relevant with load, and when transformer passed through load, active loss equaled the copper loss in the transformer, and reactive loss equals the leakage reactance loss in the winding.

Present transformer efficiency loss computing method complexity, for example enumerate several as follows for two-winding transformer power attenuation method:

Transformer active loss Δ P computing method:

ΔP＝ΔP ₀+(P ²+Q ²/U ²)r _b×10 ^-3

Or Δ P=Δ P ₀+ Δ P _k(S _a/ S _n) ²

Or $\mathrm{\ΔP}={\mathrm{\ΔP}}_0+{3I}_{1a}^2{r}_{b1}\×{10}^{-3}$

Or $\mathrm{\ΔP}={\mathrm{\ΔP}}_0+{3I}_{2a}^2{r}_{b2}\×{10}^{-3}$

Δ P in the formula ₀---the unloaded active loss of transformer, KW;

Δ P _k---the short circuit loss of transformer, KW;

I _1a---the transformer primary side is represented everyday rms current, A;

I _2a---Circuit Fault on Secondary Transformer is represented everyday rms current, A;

r _B1---transformer is every equal value resistance of benchmark with primary side voltage, Ω;

I _B2---transformer is every equal value resistance of benchmark with secondary side voltage, Ω;

r _b---the every equal value resistance of transformer, Ω;

S _a---transformer root mean square capacity, KVA;

Sn---transformer rated capacity, KVA;

U---flow through that line voltage of power, Kv;

Transformer reactive loss Δ Q computing method:

$\mathrm{\ΔQ}=\frac{I_0\%}{100}{S}_n+\frac{U_K\%\mathrm{Sn}}{100}{(S_a/S_n)}^2$

Or $\mathrm{\ΔQ}=\frac{I_0\%}{100}{S}_n+\frac{P^2+Q^2}{U^2}{X}_b\×{10}^{-3}$

Or $\mathrm{\ΔQ}=\frac{I_0\%}{100}{S}_n+3I_{1a}^2{X}_{b1}\×{10}^{-3}$

Or $\mathrm{\ΔQ}=\frac{I_0\%}{100}{S}_n+3I_{2a}^2{X}_{b2}\×{10}^{-3}$

I in the formula ₀The no-load current number percent of %---transformer;

U _kThe short-circuit voltage number percent of %---transformer;

X _b---the equivalent leakage reactance of transformer, Ω;

X _B1---transformer is every equal value leakage reactance of benchmark with primary side voltage, Ω;

X _B2---transformer is every equal value leakage reactance of benchmark with secondary side voltage, Ω;

Above computing method complexity, and the calculating of load loss supposition transformer terminal voltage all equals rated voltage and derives when arbitrary load, and virtual voltage changes with load variations, use the transformer efficiency loss that this method calculates and have error, and this computing method can not reflect the transformer efficiency loss value in real time.In addition, a certain section leeway situation can not reflect truly that long loss changes.Result calculated can only be used for management afterwards like this, and can not be as real-time control foundation.

Want to simulate truth, calculate transformer at a time or the energy loss in a certain period be very difficult because detailed electrical network data not only will be arranged, also a large amount of run books to be arranged, some run book is difficult to obtain.

Summary of the invention

It is a kind of based on the electric quantity data of synchronization primary side transformer and the electric quantity data of secondary side that goal of the invention of the present invention is to provide, deduct the data of secondary side electric weight with the electric quantity data of once surveying, provide the actual occurrence value of transformer kwh loss, instantaneous quantization data transformers loss metering method is provided.

The technical scheme that realizes the object of the invention is to solve like this:

1, a kind of transformer loss calculating correction values method comprises the steps:

The real-time dynamic data of a, collection transformer primary side and secondary side active power P, reactive power Q, general power S, power factor COS Φ;

B, deduct the corresponding electric quantity data of secondary side with the primary side electric quantity data, calculate active loss Δ P, the reactive loss Δ Q, the power factor change Δ COS Φ that provide transformer, total work loss Δ S influences the electric weight of transformer economic operation;

C, usefulness active loss Δ P are divided by the active power of synchronization primary side, the active loss Δ P/P of the meritorious electric weight of unit of account ₁

D, usefulness total work loss Δ S are divided by the general power of synchronization primary side, the total work loss Δ S/S of unit of account load ₁

E, usefulness reactive loss Δ Q are divided by the reactive power of synchronization primary side, the reactive loss Δ Q/Q of unit of account capacity of idle power ₁

F, transformer energy saving runs administrative software are set up Δ P/P ₁, Δ S/S ₁, Δ Q/Q ₁Isoparametric dynamic data base calculates Δ P/P respectively ₁, Δ S/S ₁, Δ Q/Q ₁The minimum value of parameter when the transformer economic operation state, instantaneous value and the minimum value of transformer being moved electrical quantity compare, provide difference, difference is exported control signal or alerting signal after exceeding certain limit, makes satisfied being substantially equal to of operation of transformer optimize the economical operation parameter;

Its computing formula is:

Active loss Δ P=P ₁-P ₂

Reactive loss Δ Q=Q ₁-Q ₂

Total work loss Δ S=S ₁-S ₂

Power factor reduction value Δ COS Φ=COS Φ ₁-COS Φ ₂

The active loss rate of the meritorious electric weight of unit $\mathrm{\ΔP}/P_1=\frac{P_1-P_2}{P_1}\×100\%$

The total work proportion of goods damageds of specific load $\mathrm{\ΔS}/S_1=\frac{S_1-S_2}{S_1}\×100\%$

The reactive loss rate of unit capacity of idle power $\mathrm{\ΔQ}/Q_1=\frac{Q_1-Q_2}{Q_1}\×100\%.$

The meaning of each symbology is in the formula: the loss of Δ P-smelting transformer, P ₁-primary side active power, P ₂-secondary side active power; Δ Q-reactive loss, Q ₁-primary side reactive power, Q ₂-secondary side reactive power; The loss of Δ S-total work, S ₁-primary side general power, S ₂-secondary side general power; Δ COS Φ-instantaneous power factor changing value, COS Φ ₁-primary side power factor, COS Φ ₂-secondary side power factor; The S-general power; P-active power; The Q-reactive power.

Transformer primary side and secondary side active power P according to the collector collection that is connected in transformer primary side and secondary side respectively, reactive power Q, general power S, the real-time dynamic data of power factor COS Φ, deduct the corresponding electric quantity data of secondary side with the primary side electric quantity data, calculating provides the active loss Δ P of transformer and secondary side generation thereof, reactive loss Δ Q, power factor change Δ COS Φ, total work loss Δ S etc. influences the electrical parameter of transformer economic operation, with active loss Δ P divided by the corresponding instantaneous active power of primary side, the active loss rate Δ P/P of the meritorious electric weight of unit of account ₁With the total work proportion of goods damageds Δ S/S of total work loss divided by the instantaneous general power unit of account load of corresponding primary side ₁With the instantaneous reactive power of reactive loss divided by corresponding primary side, the reactive loss rate Δ Q/Q that unit of account is idle ₁

The transformer energy saving runs administrative software that links to each other with collector is set up Δ P/P ₁, Δ S/S ₁, Δ Q/Q ₁Isoparametric dynamic data base calculates Δ P/P ₁, Δ S/S ₁, Δ Q/Q ₁Etc. the minimum value of parameter when the transformer economic operation state, instantaneous value and the minimum value of transformer being moved electrical quantity compare, provide difference, difference is exported control signal or alerting signal after exceeding certain limit, makes satisfied being substantially equal to of operation of transformer optimize the economical operation parameter.

These computing method can be in order to measure the instantaneous proportion of goods damageds when the active power P of primary side and secondary side, reactive power Q, general power S value instantaneous value; Can be when the active power P of primary side and secondary side, reactive power Q, general power S value mean value in order to calculate the average loss in a period of time.

The present invention compared with prior art, its beneficial effect is:

The present invention provides the instantaneous quantization data for transformer loss, for the control of energy consumption Real-time and Dynamic provides foundation.According to result of calculation, make the transformer energy saving runs administrative software realize real-time control to transformer loss system lowest loss, dynamic real-time shows operational factor and the lowest loss of transformer and the difference of requirement of transformer, the back warning that goes beyond the scope and guides the transformer energy saving operation, make satisfied being substantially equal to of operation of transformer optimize the economical operation parameter, thereby reduce the energy loss of transformer to greatest extent and improve the power factor of its mains side, and then realize increasing output, energy-saving and cost-reducing effect.

For electric power person in charge science is calculated power supply reliability, the transformer transformation provides the most basic data,, provide reliable basis by a large amount of accurate and visual data for operation of power networks quality high-quality, stable advanced applied software more.

Embodiment

Below in conjunction with embodiment content of the present invention is described further:

Computing formula:

Active loss Δ P=P ₁-P ₂

Reactive loss Δ Q=Q ₁-Q ₂

Total work loss Δ S=S ₁-S ₂

Power factor reduction value Δ COS Φ=COS Φ ₁-COS Φ ₂

The active loss rate of the meritorious electric weight of unit $\mathrm{\ΔP}/P_1=\frac{P_1-P_2}{P_1}\×100\%$

The total work proportion of goods damageds of specific load $\mathrm{\ΔS}/S_1=\frac{S_1-S_2}{S_1}\×100\%$

The reactive loss rate of unit capacity of idle power $\mathrm{\ΔQ}/Q_1=\frac{Q_1-Q_2}{Q_1}\×100\%$

Embodiment 1

1. calculate the instantaneous power loss:

Calculate for example with the 12500KVA ore heat furnace transformer:

The transformer primary side that synchronization collector 1 and collector 2 are gathered and secondary side instantaneous active power P, instantaneous reactive power Q, instantaneous general power S, instantaneous power factor COS Φ are respectively: S ₁=12500KVA, P ₁=10000KW, Q ₁=7500Kvar, COS Φ ₁=0.8, S ₂=11000KVA, P ₂=9130KW, Q ₂=6135Kvar,, COS Φ ₂=0.83

This instantaneous power loss constantly is calculated as follows:

Active loss Δ P=P ₁-P ₂=10000-9130=870KW

Reactive loss Δ Q=Q ₁-Q ₂=7500-6135=1365Kvar

Total work loss Δ S=S ₁-S ₂=12500-11000=1500KVA

Power factor change value Δ COS Φ=COS Φ ₁-COS Φ ₂=0.8-0.83=-0.03

The active loss rate of the meritorious electric weight of unit $\mathrm{\ΔP}/P_1=\frac{P_1-P_2}{P_1}\×100\%$

$=\frac{870}{10000}\×100\%=8.7\%$

The total work proportion of goods damageds of specific load $\mathrm{\ΔS}/S_1=\frac{S_1-S_2}{S_1}\×100\%$

$=\frac{1500}{12500}\×100\%=12\%$

The reactive loss rate of unit capacity of idle power $\mathrm{\ΔQ}/Q_1=\frac{Q_1-Q_2}{Q_1}\×100\%$

$=\frac{1365}{7500}\×100\%=18.2\%$

Calculating average power loss: when the data of collector 1 and collector 2 collections are the mean value of a period of time, then be the average power consumption value with above formula result of calculation.

Claims (2)

1, a kind of transformer loss calculating correction values method is characterized in that comprising the steps:

The real-time dynamic data of a, collection transformer primary side and secondary side active power P, reactive power Q, general power S, power factor COS Φ;

B, deduct the corresponding electric quantity data of secondary side with the primary side electric quantity data, calculate active loss Δ P, the reactive loss Δ Q, the power factor change Δ COS Φ that provide transformer, total work loss Δ S influences the electric weight of transformer economic operation;

C, usefulness active loss Δ P are divided by the active power of synchronization primary side, the active loss Δ P/P of the meritorious electric weight of unit of account ₁

D, usefulness total work loss Δ S are divided by the general power of synchronization primary side, the total work loss Δ S/S of unit of account load ₁

E, usefulness reactive loss Δ Q are divided by the reactive power of synchronization primary side, the reactive loss Δ Q/Q of unit of account capacity of idle power ₁

F, transformer energy saving runs administrative software are set up Δ P/P ₁, Δ S/S ₁, Δ Q/Q ₁Isoparametric dynamic data base calculates Δ P/P respectively ₁, Δ S/S ₁, Δ Q/Q ₁The minimum value of parameter when the transformer economic operation state, instantaneous value and the minimum value of transformer being moved electrical quantity compare, provide difference, difference is exported control signal or alerting signal after exceeding certain limit, makes satisfied being substantially equal to of operation of transformer optimize the economical operation parameter;

Its computing formula is:

Active loss Δ P=P ₁-P ₂

Reactive loss Δ Q=Q ₁-Q ₂

Total work loss Δ S=S ₁-S ₂

Power factor reduction value Δ COS Φ=COS Φ ₁-COS Φ ₂

The active loss rate of the meritorious electric weight of unit $\mathrm{\ΔP}/P_1=\frac{P_1-P_2}{P_1}\×100\%$

The total work proportion of goods damageds of specific load $\mathrm{\ΔS}/S_1=\frac{S_1-S_2}{S_1}\×100\%$

The reactive loss rate of unit capacity of idle power $\mathrm{\ΔQ}/Q_1=\frac{Q_1-Q_2}{Q_1}\×100\%$

The meaning of each symbology is in the formula: the loss of Δ P-smelting transformer, P ₁-primary side active power, P ₂-secondary side active power; Δ Q-reactive loss, Q ₁-primary side reactive power, Q ₂-secondary side reactive power; The loss of Δ S-total work, S ₁-primary side general power, S ₂-secondary side general power; Δ COS Φ-instantaneous power factor changing value, COS Φ ₁-primary side power factor, COS Φ ₂-secondary side power factor; The S-general power; P-active power; The Q-reactive power.

2, transformer loss calculating correction values method according to claim 1 is characterized in that these computing method can be in order to measure the instantaneous proportion of goods damageds or the average loss in calculating a period of time.