RU71445U1 - DEVICE FOR OPERATIONAL MONITORING AND PROTECTION OF TRANSFORMER WINDING - Google Patents

Abstract

The utility model relates to electrical engineering, and can be used for operational monitoring and protection of transformer windings in operating mode. The objective of the utility model is to create a more reliable and efficient device for the operational monitoring and protection of transformer windings, which allows controlling the active resistance of the transformer windings directly in the operating mode and using it to determine the inductance of the windings and as a diagnostic indicator. The task is achieved in that the device for the operational control and protection of the transformer windings in the operating mode comprises a primary voltage measuring transducer connected to the primary winding of the transformer, secondary voltage and secondary current measuring transducers connected to the secondary winding of the transformer. Moreover, each of the measuring transducers is connected to a series-connected switch and an analog-to-digital converter, to which a reduction unit and a difference calculation unit are connected, which is connected to a resistance calculation unit and to an inductive voltage component unit, which is connected to an inductance calculation unit, which is connected in series connected by an averaging unit and a control programmer connected to the button keyboard. Moreover, the reduction unit is connected to the difference calculation unit, the resistance calculation unit, the inductive voltage component unit, and to the differentiation unit, which is connected to the inductance calculation unit. And the resistance calculation unit is connected with the inductive voltage component unit and with the control programmer.

Description

The utility model relates to electrical engineering, and can be used for operational monitoring and protection of transformer windings in operating mode.

A device for monitoring and protecting transformer windings from winding deformations during short circuits is known [RF Patent No. 2136099 IPC G01R 31/02. Stated 06/10/94; Publ. 08.27.99.], Containing a three-phase power supply, each phase of which is connected to the first terminals of a three-phase protective switch, the second terminals of the primary winding of a three-phase controlled transformer are connected to a common terminal, the outputs of the current-measuring elements included in the circuit of each phase of the secondary winding are connected to the inputs of the unit calculating the derivative of the current, the outputs of which are connected to the corresponding inputs of the inductance calculation unit, the first, second and third inputs of which are connected to the corresponding the outputs of the unit for calculating the average voltage value. The outputs of the unit for calculating the average value of inductance for a period are connected to the corresponding inputs of the unit for calculating the deviation, the other inputs of which are connected to the outputs of the unit for setting the inductance, the outputs of which are connected to the inputs of the unit for controlling the inductance deviation, the first and second outputs of which are connected respectively to the seventh input of the unit for calculating the current derivative and the fourth input of the average voltage value calculation unit, and the third - with the input of the protection unit, the output of which is connected to the control input t a phase-protective circuit breaker, the input terminals of a three-phase primary voltage transformer are connected to the corresponding phases of a three-phase power supply. The current-measuring element is made in the form of a current transformer. The first, second and third inputs of the unit for bringing the inductance value to the nominal frequency are connected to the corresponding outputs of the inductance calculation unit. The fourth and fifth inputs of the unit for bringing the inductance value to the nominal frequency are connected respectively to the first and second outputs of the frequency meter, which is connected between the first terminals of the second and third current transformers. The first, second and third outputs of the unit for bringing the inductance value to the nominal frequency are connected to the corresponding inputs of the unit for calculating the average inductance value for the period. The first, second and third inputs of the block bringing the primary voltage to

the secondary are connected respectively to the output terminals of the three-phase transformer of the primary voltage. The first, second and third inputs of the voltage difference calculation unit are connected respectively to the outputs of the primary voltage reduction unit to the secondary, and the fourth, fifth and sixth inputs of the voltage difference calculation unit are connected respectively to the outputs of the first, second and third secondary voltage transformers. The first, second and third outputs of the voltage difference calculation unit are connected to the corresponding inputs of the average voltage value calculation unit. The first, second, third, fourth, fifth and sixth inputs of the unit for calculating the voltage drop across the active resistance of the transformer are connected to the corresponding terminals of the current transformers, the seventh, eighth and ninth inputs of which are connected to the corresponding outputs of the transformer active resistance setting unit. The first, second and third outputs of the unit for calculating the voltage drop across the active resistance of the transformer are connected respectively to the additional seventh, eighth and ninth inputs of the unit for calculating the inductance. The first conclusions of the secondary winding of a three-phase controlled transformer are interconnected according to the "star" scheme. The second terminals of the corresponding secondary winding are connected through the corresponding current transformers to the first terminals of the secondary voltage transformers and connected to the active load, and the first terminals of the primary winding of the three-phase controlled transformer are connected to the second terminals of the three-phase protective switch.

A disadvantage of the known device is that the value of the active resistance of the transformer windings is determined either by calculations or by the results of a preliminary experiment, which leads to inaccuracies in determining the inductance of the windings and does not allow the active resistance of the windings to be used as a diagnostic indicator. This disadvantage leads to a decrease in the reliability and effectiveness of the described device.

The objective of the utility model is to create a more reliable and efficient device for the operational monitoring and protection of transformer windings, which allows controlling the active resistance of the transformer windings directly in the operating mode and using it to determine the inductance of the windings and as a diagnostic indicator.

The task is achieved in that the device for the operational control and protection of the transformer windings in the operating mode comprises a primary voltage measuring transducer connected to the primary winding of the transformer,

secondary voltage and secondary current transducers connected to the secondary winding of the transformer. Moreover, each of the measuring transducers is connected to a series-connected switch and an analog-to-digital converter, to which a reduction unit and a difference calculation unit are connected, which is connected to a resistance calculation unit and to an inductive voltage component unit, which is connected to an inductance calculation unit, which is connected in series connected by an averaging unit and a control programmer connected to the button keyboard. Moreover, the reduction unit is connected to the difference calculation unit, the resistance calculation unit, the inductive voltage component unit, and to the differentiation unit, which is connected to the inductance calculation unit. And the resistance calculation unit is connected with the inductive voltage component unit and with the control programmer.

The proposed circuit of the claimed device is more reliable and effective due to the fact that the active resistance of the transformer windings is controlled directly in the operating mode and used to determine the inductance of the windings and as a diagnostic indicator.

Figure 1 - shows the hardware circuit of the device for operational monitoring and protection of the transformer windings.

A device for the operational monitoring and protection of transformer windings contains three measuring transducers, each of which is connected to a switch that is connected to an analog-to-digital converter (not shown in FIG. 1), reduction unit 1 (BPR), difference calculation unit 2 (BVR) , block for calculating resistance 3 (BVS), block for inductive component of voltage 4 (BISN), block for differentiation 5 (BD), block for calculating inductance 6 (BVI), averaging block 7 (BUSr) and control programmer 8 (П).

A primary voltage measuring transducer is connected to the transformer primary winding, secondary voltage and secondary current measuring transducers are connected to the secondary winding of the transformer, each of the measuring transducers being connected to a switch and an analog-to-digital converter connected in series (not shown in Fig. 1). The corresponding inputs of the cast unit 1 (BPR) and the difference calculation unit 2 (BVR) are connected to an analog-to-digital converter. The inputs of the control programmer 8 (P) are connected to a button keyboard (not shown in FIG. 1). The outputs of the reduction unit 1 (BPR) are connected to the corresponding inputs of the difference calculation unit 2 (BVR), the resistance calculation unit 3 (BVS), the inductive voltage component unit 4

(BISN) and differentiation unit 5 (DB). The output of the difference calculation unit 2 (BVR) is connected to the corresponding inputs of the resistance calculation unit 3 (BVS) and the inductive voltage component unit 4 (BISN). The output of the resistance calculation unit 3 (BVS) is connected to the corresponding inputs of the inductive voltage component 4 (VISN) and the control programmer 8 (P). The outputs of the inductive voltage component block 4 (BISN) and the differentiation unit 5 (DB) are connected to the corresponding input of the inductance calculation unit 6 (BVI), the output of which is connected to the input of the averaging unit 7 (BUSr), the output of which is connected to the corresponding input of the control programmer 8 ( P).

Reduction unit 1 (BPR), difference calculation unit 2 (BVR), resistance calculation unit 3 (BVS), inductive voltage component block 4 (BISN), differentiation unit 5 (DB), inductance calculation unit 6 (BVI), averaging block 7 (Busr) and control programmer 8 (P) can be performed on the microcontroller of the 51 series atmel AT89S53.

The device operates as follows. When the transformer is operating in a close to nominal mode through three measuring transducers connected to its windings, each of which is connected to a switch and an analog-to-digital converter (not shown in FIG. 1) connected to the inputs of the reduction unit 1 (BPR) and the block calculating the difference 2 (BVr), as shown in figure 1, serves arrays of instantaneous values of the secondary current i ₂ (t), input and output voltages u _I (t) and u _n (t). In the control programmer 8 (P), enter the values of the active resistances _{Rspr of the} leakage inductance of the windings _Lpr , determined on a known-good transformer.

In block cast 1 (BPR) arrays of instantaneous values of the secondary current and voltage on the secondary winding lead to the primary circuit according to the formulas

where W ₁ is the number of turns of the primary winding;

W ₂ - the number of turns of the secondary winding.

From the output of the casting unit 1 (BPR) an array of instantaneous values of the reduced voltage of the secondary winding arrives at the input of the difference calculation unit 2 (BVr). In the unit for calculating the difference 2 (BVr) find the difference of the reduced voltage of the primary and secondary windings of the transformer

Instantaneous voltage difference across transformer windings | u ₁₂ (t _j ) | enter the input of the resistance calculation unit 3 (BVS) and the inductive voltage component unit 4 (VISN).

Simultaneous instantaneous values of the reduced secondary current from the output of the casting unit 1 (BPR), they enter the input of the differentiation unit 5 (DB), the input of the resistance calculation unit 3 (BVS), and the input of the inductive voltage component 4 (BISN).

In the block for calculating the resistance 3 (BVS), the value of the power of active losses P ₁₂ in the transformer windings is calculated from the arrays of instantaneous current values and voltages | u ₁₂ (t _j ) | [Functional control and diagnostics of electrical and electromechanical systems and devices based on digital readings of instantaneous values of current and voltage // Ed. E.I. Goldstein. Tomsk: Printing manufactory, 2003. - 240 p.]

The effective value of the reduced secondary current is determined

Determine the active resistance of the transformer windings

The value of the active resistance of the windings R ₁₂ from the output of the resistance calculation unit 3 (BVS) is fed to the input of the inductive voltage component 4 (VISN) and to the input of the control programmer 8 (P).

In the unit for calculating the inductive component of voltage 4 (VISN), the inductive component of the voltage difference is found by subtracting from the difference of the reduced voltages on the transformer windings its active component obtained by the product of the active resistance of the windings by the reduced current of the secondary winding

An array of instantaneous values of the inductive component of the voltage difference | u _L (t _j ) | (arrives at the input of the inductance calculation unit 6 (BVI).

In block differentiation 5 (DB) produce numerical differentiation of the array of instantaneous values of the reduced current of the secondary winding , and get an array of values of the derivative of the specified current with respect to time. For numerical differentiation, in particular, the formula [G. Korn, T. Korn. Handbook of mathematics for scientists and engineers - M., 1974, 832 p. P.696]

Array of instantaneous values of the derivative of the secondary current with respect to time arrives at the input of the inductance calculation unit 6 (BVI).

The instantaneous values of the inductance of the transformer windings defined in the inductance calculation unit 6 (BVI)

arrive at the input of the averaging unit 7 (BUSr).

In the averaging block 7 (BUSr) exclude peak values of the instantaneous inductance | L (t _j ) | and calculate the average value for the period

which is fed to the input of the control programmer 8 (P).

In the control programmer 8 (P), the relative deviations of the inductance and active resistance of the windings from the values obtained on a known-good transformer are calculated according to the formulas

Further, in programmer 8 (P), the relative deviations ΔL and ΔR _{12 are} compared with the setting ε, which is determined empirically for each specific case. If the values of ΔL and ΔR _{12 are} less than ε, then the transformer windings are in good condition. Thus, at the output of the control programmer 8 (P) there will be a signal about the working condition of the transformer windings and a trip signal will not be given. If the value of one of the relative deviations from the values for a known-good transformer exceeds the set value, the output of the programmer

The control will signal that the corresponding transformer winding is in a faulty condition and a signal will be sent to turn off the transformer.

Claims (1)

A device for the operational monitoring and protection of transformer windings in operating mode, characterized in that a primary voltage measuring transducer is connected to the transformer primary winding, secondary voltage and secondary current measuring transducers are connected to the secondary winding of the transformer, each of the measuring transducers being connected to a series-connected switch and an analog-to-digital converter, to which a cast unit and a difference calculation unit are connected, which th is connected to the resistance calculation unit and to the inductive voltage component unit, which is connected to the inductance calculation unit, which is connected to the averaging unit and the control programmer connected in series with the keypad, the reduction unit being connected to the difference calculation unit, the resistance calculation unit, the unit the inductive component of the voltage and to the differentiation unit, which is connected to the inductance calculation unit, and the resistance calculation unit is connected to the unit m inductive voltage component and the programmer controls.