RU88159U1 - DEVICE FOR MONITORING THE TECHNICAL CONDITION OF SINGLE-PHASE AND THREE-PHASE TWO-WAY TRANSFORMERS IN OPERATING MODE - Google Patents

Abstract

A device for monitoring the technical condition of single-phase and three-phase two-winding transformers in operating mode, containing an electrical signal recorder connected through a switch to current and voltage transformers of a two-winding transformer measurement circuit, characterized in that the outputs of the electrical signal recorder are connected to the input of the unit for calculating the effective current values, inputs unit for calculating the effective values of stresses, inputs of the unit for calculating the angle of phase shift between voltages, inputs of the unit calculating the phase angle between voltage and current, the outputs of the unit for calculating the effective current values are connected to the input of the unit for calculating the angle of the phase between voltage and current and the input of the current bringing unit, the outputs of the unit for calculating the effective voltage values are connected to the inputs of the unit for calculating the phase angle between the voltages, with the input of the unit for calculating the angle of phase shift between voltage and current and the input of the unit for bringing the current, one of the inputs of the unit for bringing the current is connected to the output of the network frequency measuring device, the outputs of the unit for calculating the angle s the motor phase between voltage and current and the current supply unit are connected to the inputs of the active current component calculation unit and the inputs of the reactive current component calculation unit, the output of the phase angle angle calculation unit between the voltages is connected to the input of the coefficient calculation unit, the outputs of the active current component calculation unit and the calculation unit the reactive component of the current is connected to the inputs of the coefficient calculation block and the inputs of the control angle calculation block, the output of the coefficient calculation block is connected to the input of the control calculation block

Description

The utility model relates to the field of electromechanics, namely, to the use of information processing tools in electromechanics, and can be used to monitor the technical condition of single-phase and three-phase double-winding transformers in operating mode.

A device for the operational control and protection of the windings of transformers [Pat. RF 71445, IPC G01R 31/02. Device for operational control and protection of transformer windings / E.I. Goldstein, A.V. Pankratov. - Stated August 27, 2007; publ. 10.03.2008], selected as a prototype, in which a primary voltage measuring transducer is connected to the primary winding of the transformer, secondary voltage and secondary current measuring transducers are connected to the secondary winding of the transformer. 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 to series-connected an averaging unit and a control programmer connected to the button keyboard. The reduction unit is connected to the difference calculation unit, the resistance calculation unit, the inductive voltage component unit and the differentiation unit, which is connected to the inductance calculation unit. The resistance calculation unit is connected to the inductive voltage component unit and to the control programmer.

The disadvantages of the known device:

- the use of the drive unit in this device may lead to incorrect operation of the entire device in case of a change in the actual transformation coefficient of the controlled transformer, while this device does not allow to determine the exact transformation coefficient of the transformer in its operating modes;

The objective of the proposed utility model is the creation of a device for monitoring the technical condition of single-phase and three-phase double-winding transformers in operating mode, which allows you to quickly receive information about changes in the technical condition of transformers, using only the data received on the controlled transformer from the moment it was controlled using this device.

The problem is solved due to the fact that the device for monitoring the technical condition of single-phase and three-phase double-winding transformers in operating mode, as well as a prototype, contains an electrical signal recorder connected through a switch to current and voltage transformers of the measurement circuit of a double-winding transformer (Fig. 1).

Unlike the prototype, the outputs of the electrical signal recorder are connected to the input of the unit for calculating the effective current values, the inputs of the unit for calculating the effective voltage values, the inputs of the unit for calculating the phase angle between the voltages, the inputs of the unit for calculating the phase angle between the voltage and current. The outputs of the unit for calculating the effective current values are connected to the input of the unit for calculating the phase angle between voltage and current and the input of the unit for bringing the current. The outputs of the unit for calculating the effective values of the voltages are connected to the inputs of the unit for calculating the phase angle between the voltages, with the input of the unit for calculating the phase angle between voltage and current and the input of the current driving unit. One of the inputs of the current driving unit is connected to the output of the network frequency measuring device. The outputs of the unit for calculating the phase angle between voltage and current and the unit for bringing the current are connected to the inputs of the unit for calculating the active component of the current and the inputs of the unit for calculating the reactive component of the current. The output of the block for calculating the angle of phase shift between the voltages is connected to the input of the block for calculating the coefficients. The outputs of the active current component calculation unit and the reactive current component calculation unit are connected to the inputs of the coefficient calculation unit and the inputs of the control angle calculation unit. The output of the coefficient calculation block is connected to the input of the control angle calculation block. The output of the block for calculating the angle of phase shift between the voltages and the output of the block for calculating the control angle are connected to the inputs of the block for calculating the deviations of the angle, the output of which is connected to the data acquisition and transmission device.

Thus, the proposed device allows for three different load conditions to determine the dependence of the phase angle between the voltages of the primary and secondary windings from the load mode of the transformer for its current technical condition. This makes it possible to monitor the technical condition of both single-phase and three-phase two-winding transformers by deviating the phase angle between the voltages of the primary and secondary windings, determined by arrays of instantaneous voltage values for any operating mode of the transformer, from the value of the control phase angle between the primary voltages and secondary windings. There is no need to have information about the design of the transformer and, in particular, its winding data.

Figure 1 presents the measurement circuit of a single-phase double-winding transformer in operating mode.

Figure 2 presents the hardware diagram of the device for operational monitoring of the technical condition of single-phase and three-phase double-winding transformers by the angle of phase shift between the primary and secondary voltage in the operating mode.

The electrical signal recorder 1 (RES) is connected through a switch to current and voltage transformers of the measurement circuit of a double-winding transformer (Fig. 1). The outputs of the recorder are connected to the input of the unit for calculating the effective values of current 2 (BRT), the inputs of the unit for calculating the effective values of voltages 3 (BRN), the inputs of the unit for calculating the phase angle between voltages 4 (BRFn-n), the inputs of the unit for calculating the phase angle between the voltage and current 5 (BRFn-t). The outputs of the unit for calculating the effective values of current 2 (BRT) are connected to the input of the unit for calculating the phase angle between voltage and current 5 (BRFn-t) and the input of the unit for bringing current 6 (BPT). The outputs of the unit for calculating the effective values of the voltages 3 (BRN) are connected to the inputs of the unit for calculating the phase angle between the voltages 4 (BRFn-n), with the input of the unit for calculating the phase angle between the voltage and current 5 (BRFn-t) and the input of the current driving unit 6 (BPT). One of the inputs of the current driving unit 6 (BTC) is connected to the output of the network frequency measuring device (not shown in FIG. 2). The outputs of the unit for calculating the phase angle angle between voltage and current 5 (BRFn-t) and the unit for bringing current 6 (BPT) are connected to the inputs of the unit for calculating the active component of current 7 (BRAT) and the inputs of the unit for calculating the reactive component of current 8 (BRT). The output of the block for calculating the angle of the phase shift between the voltages 4 (BRFn-n) is connected to the input of the block for calculating the coefficients 9 (DBK). The outputs of the unit for calculating the active component of current 7 (BRAT) and the unit for calculating the reactive component of current 8 (BRT) are connected to the inputs of the unit for calculating the coefficients 9 (BRC) and the inputs of the unit for calculating the control angle 10 (BRCU). The output of the unit for calculating the coefficients 9 (DBK) is connected to the input of the unit for calculating the control angle 10 (BRKU). The output of the block for calculating the angle of the phase shift between the voltages 4 (BRFn-n) and the output of the block for calculating the control angle 10 (BRKU) are connected to the inputs of the block for calculating the deviations of the angle 11 (BROF), the output of which is connected to the data acquisition and transmission device (Fig. 2 not shown).

As the recorder of electrical signals 1 (RES) can be selected digital recorder of electrical signals of the type "Parma" or "Black box". The unit for calculating the effective values of current 2 (BRT), the unit for calculating the effective values of voltages 3 (BRN), the unit for calculating the phase angle between the voltages 4 (BRFn-n), the unit for calculating the angle of the phase shift between voltage and current 5 (BRFn-t), current reduction unit 6 (BPT), active current component calculation unit 7 (BRAT), reactive current component calculation unit 8 (BRRT), coefficient calculation unit 9 (BRK), control angle calculation unit 10 (BRKU), angle deviation calculation unit 11 (BROW) can be performed on a C51 series microcontroller manufactured by Atmel AT89S8253.

During the operation of the transformer, when its primary winding is connected to a power source, and the load is connected to the secondary winding, using arrays of electrical signals 1 (RES) in the operating mode for the same moments of time, arrays of instantaneous values of the primary current and primary voltages are recorded the secondary windings of the transformer with a certain discreteness in time Δt, corresponding to the number of samples in the period N.

From the output of the electrical signal recorder 1 (RES) an array of instantaneous values of the primary current arrives at the input of the unit for calculating the phase angle between voltage and current 5 (BRFn-t) and at the input of the unit for calculating the effective values of current 2 (BRT) in which the effective value of the primary current is determined from the array of instantaneous current values

where N is the number of samples of instantaneous values on the current period;

From the output of the unit for calculating the effective values of current 2 (BRT), the data on the effective value of the current of the primary winding I ₁ are fed to the input of the unit for calculating the phase angle between voltage and current 5 (BRFn-t) and the unit for bringing the current 6 (BPT).

From other outputs of the recorder of electrical signals 1 (RES) an array of instantaneous values of the primary voltage goes to the input of the unit for calculating the effective values of voltages 3 (BRN), the input of the unit for calculating the phase angle between voltages 4 (BRFn-n) and the input of the unit for calculating the phase angle between voltages and current 5 (BRFn-t), and the array of instantaneous voltage values secondary winding arrives at the input of the unit for calculating the effective values of stresses 3 (BRN) and the input of the unit for calculating the angle of phase shift between voltages 4 (BRFn-n).

In the block for calculating the effective values of voltages 3 (BRN) for arrays of instantaneous voltage values of the primary and secondary windings , determine:

-the effective value of the voltage of the primary winding

where N is the number of samples of instantaneous values on the voltage period;

- the effective value of the voltage of the secondary winding

From the outputs of the unit for calculating the effective values of voltages 3 (BRN), information about the effective value of the voltage of the primary winding U _{1 is} fed to the input of the unit for calculating the phase angle between voltages 4 (BRFn-n), the input of the unit for calculating the phase angle between voltage and current 5 (BRFn -t) and the input of the current driving unit 6 (BPT), and the effective value of the voltage of the secondary winding U _{2 is} fed to the input of the unit for calculating the phase angle between the voltages 4 (BRFn-n).

In the block for calculating the phase angle between voltage and current 5 (BRFn-t) for arrays of instantaneous voltage values and current the primary winding and the current values of the voltage U ₁ and current I _{1 of the} primary winding determine the angle of phase shift between the voltage and current of the primary winding of the transformer

From the output of the block for calculating the phase angle between voltage and current 5 (BRFn-t), the value of the phase angle between voltage and current of the primary winding of the transformer arrives at the input of the unit for calculating the active component of current 7 (BRAT) and the input of the unit for calculating the reactive component of current 8 (BRT).

In the block for calculating the phase angle between the voltages 4 (BRFn-n) for arrays of instantaneous voltage values of the primary and secondary windings , and the current values of the voltages of the primary and secondary windings U ₁ , U ₂ determine the angle of phase shift between the voltages of the primary and secondary windings of the transformer

From the output of the block for calculating the phase angle between the voltages 4 (BRFn-n) the value of the phase angle between the voltages of the primary and secondary windings of the transformer arrives at the corresponding input of the coefficient calculation block 9 (DBK).

In the current driving unit 6 (BPT), the current value of the primary current I ₁ leads to the rated voltage of the primary winding U _nom and the rated frequency of the network f _nom , according to the current value of the voltage of the primary winding U ₁ and the value of the network frequency f ₁ measured during the period registration of arrays of instantaneous values of current and voltage using a frequency measuring device

From the output of the current driving unit 6 (BPT), the reduced effective value of the primary current is arrives at the input of the unit for calculating the active component of current 7 (BRAT) and the input of the unit for calculating the reactive component of current 8 (BRT).

In the block for calculating the active component of current 7 (BRAT) by the value of the phase angle between the voltage and the current of the primary winding of the transformer and the value of the effective value of the reduced current of the primary winding determine the value of the effective value of the active component of the reduced current of the primary winding

From the output of the unit for calculating the active component of current 7 (BRAT), data on the value of the effective value of the active component of the reduced current of the primary winding arrive at the input of the coefficient calculation block 9 (DBK).

In the unit for calculating the reactive component of current 8 (BRRT) by the value of the phase angle between the voltage and current of the primary winding of the transformer and the magnitude of the reduced rms value of the primary current determine the value of the effective value of the reactive component of the reduced current of the primary winding

From the output of the unit for calculating the reactive component of current 8 (BRRT) data on the value of the effective value of the reactive component of the reduced current of the primary winding arrive at the input of the coefficient calculation block 9 (DBK).

In the block for calculating the coefficients 9 (DBK) according to the results of calculations for a given load mode, a package of basic data on the angle of phase shift between the voltages of the primary and secondary windings is formed active values and reactive components of the reduced current of the primary winding. Where index b ₁ - indicates the values belong to the first package of basic data.

Further, repeating the above sequence of actions, determine the phase angle between the voltages of the primary and secondary windings effective values of active and reactive components of the reduced current of the primary winding for two more modes of operation of the transformer with different active-inductive loads and, according to the results in the block for calculating the coefficients 9 (DBK) form two data packets corresponding to these modes and including: data on the phase angle between the voltages of the primary and secondary windings , active values , and reactive , components of the reduced current of the primary winding. Where the indices b2 and b3 - indicate that the values belong to the first and third packages of basic data, respectively.

According to the specified basic data on three different load conditions in the block calculation of the coefficients 9 (DBK) determine the coefficients of the equation of the characteristic plane A, B, C:

From the output of the block for calculating the coefficients 9 (DBK), the coefficients of the equation of the characteristic plane A, B, C go to the input of the block for calculating the control angle 10 (BRKU).

Then, according to the previously indicated sequence for any load mode, the phase angle between the voltages of the primary and secondary windings is determined active values and reactive components of the reduced current of the primary winding.

Information about the effective value of the active component of the reduced current of the primary winding from the output of the unit for calculating the active component of current 7 (BRAT) and information about the current value of the reactive component of the reduced current of the primary winding from the output of the unit for calculating the reactive component of the current 8 (BRRT) are fed to the input of the unit for calculating the control angle 10 (BRKU).

In the block for calculating the control angle 10 (BRKU) according to the active values of the active and reactive the components of the reduced current of the primary winding and the coefficients of the equation of the characteristic plane A, B, C determine the value of the control angle of the phase shift between the voltages of the primary and secondary windings corresponding to the current load mode of the transformer in its original technical condition

From the output of the block for calculating the control angle 10 (BRKU), the value of the control angle of the phase shift between the voltages of the primary and secondary windings is input to the block for calculating the deviations of the angle 11 (BROW).

At the other input of the block for calculating the deviations of the angle 11 (BROW) from the output of the block for calculating the phase angle between the voltages 4 (BRFn-n), the value of the phase angle between the voltages of the primary and secondary windings of the transformer .

In the block for calculating the deviations of the angle 11 (BROW) determine the deviation of the angle of the phase shift between the voltages of the primary and secondary windings of the current mode from the value of the control angle of the phase shift between the voltages of the primary and secondary windings

As the final result, at the output of the block for calculating the deviations of the angle 11 (BROW), the value of the deviation of the phase angle between the voltages of the primary and secondary windings of the current mode from the value of the control angle of the phase shift between the voltages of the primary and secondary windings Δ is obtained.

From the output of the block for calculating the deviations of the angle 11 (BROW), the value of the deviation of the phase angle between the voltages of the primary and secondary windings of the current mode from the value of the control angle of the phase shift between the voltages of the primary and secondary windings Δ is fed to the input of the data acquisition and transmission device. Further, taking into account the direct relationship of the phase angle between the voltages of the primary and secondary windings with the resistances of the windings, it can be used to generate a signal about a change in the technical condition of the transformer when the deviation exceeds the permissible limits.

The ability to determine the phase angle between the primary and secondary voltage of the double-winding transformer in its operating modes, together with the ability to determine the deviation of this angle from the control value, allows you to quickly monitor the technical condition of single-phase and three-phase double-winding transformers in operating modes.

Claims (1)

A device for monitoring the technical condition of single-phase and three-phase two-winding transformers in operating mode, containing an electrical signal recorder connected through a switch to current and voltage transformers of a two-winding transformer measurement circuit, characterized in that the outputs of the electrical signal recorder are connected to the input of the unit for calculating the effective current values, inputs unit for calculating the effective values of stresses, inputs of the unit for calculating the angle of phase shift between voltages, inputs calculating the phase angle between voltage and current, the outputs of the unit for calculating the effective current values are connected to the input of the unit for calculating the phase angle between the voltage and current and the input of the current bringing unit, the outputs of the unit for calculating the effective voltage values are connected to the inputs of the unit for calculating the phase angle between the voltages, with the input of the unit for calculating the angle of phase shift between voltage and current and the input of the unit for bringing the current, one of the inputs of the unit for bringing the current is connected to the output of the network frequency measuring device, the outputs of the unit for calculating the angle s the motor phase between voltage and current and the current supply unit are connected to the inputs of the active current component calculation unit and the inputs of the reactive current component calculation unit, the output of the phase angle angle calculation unit between the voltages is connected to the input of the coefficient calculation unit, the outputs of the active current component calculation unit and the calculation unit the reactive component of the current is connected to the inputs of the coefficient calculation block and the inputs of the control angle calculation block, the output of the coefficient calculation block is connected to the input of the control calculation block of the angle calculation unit output phase angle between the voltages and the output control angle calculation unit are connected to inputs of the block for calculating the angle deviation, the output of which is connected to the device and data collection.