RU2709094C1 - Three-phase alternating voltage corrector - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering and can be used for powering general industrial plants and other electric power consumers with supply voltage of 380/220 V. Three-phase alternating voltage corrector comprises three identical phase correctors, ballast resistor shunted by closed contact of common contactor, control system, each of the phase correctors comprises a measuring transformer with primary, secondary and additional windings, the primary winding of which is connected to the corresponding phase voltage, and secondary winding is connected to control system, power transformer with primary and secondary windings, secondary winding input and output are respectively connected to phase voltage and to load, and primary winding is connected in diagonal formed by closed and open contacts of first and second contactors. Additionally, there is an automatic circuit breaker, the first pole of which connects input of primary winding of one of measuring transformers to phase voltage, at that its additional winding is connected to control system, and the second pole connects three-phase voltage neutral to control system, to outputs of primary windings of measuring transformers, to ballast resistor common for all phase correctors, in each of which there are varistors connected in parallel to primary windings of power transformers.

EFFECT: reduction of weight and dimensions and protection against internal short circuits.

1 cl, 1 dwg

Description

The invention relates to the field of electrical engineering and can be used to power general industrial installations and other consumers of electricity with a supply voltage of 380 / 220V. A voltage regulator is known that contains input and output terminals, a voltage sensor, a transformer, the primary winding of which is included in the first diagonal of the bridge circuit of four controlled keys, the secondary winding of the transformer is connected in series to the load circuit and a controlled key is connected in parallel with it. Management keys are controlled by a three-position comparator through the first and second delay elements (RU Patent No. 2346318, IPC Н02М 5/12, G05F 1/30, publ. 2009).

A disadvantage of the known controller is its low reliability due to the possible failure of the controlled keys when the primary winding of the transformer is open.

Known multi-stage AC voltage stabilizer containing a transformer, a switching unit containing switching elements, the first and second switching relays, while the switching unit is made in the form of opening and closing contacts, shunted by RC circuits, a capacitor is connected in parallel with the transformer primary, the closing contact is connected by one output to the connection point of the NC contact and the primary winding of the transformer, another output to the neutral wire, a comparison and control device Lenia (RU, patent №2237270, IPC N02M 5/12, G05F 1/30, publ. 2004).

A disadvantage of the known stabilizer is the large overall dimensions due to the use of tanks and RC - circuits.

Known AC voltage stabilizer, adopted for the prototype, containing a transformer and a switching unit, a limiting resistor shunted by the make contact of the intermediate element, a capacitor is connected in parallel with the transformer primary winding, a comparison and control device made in the form of two identical monitoring and control circuits, the outputs of which are connected to auxiliary power source, the input of which is connected to the phase and neutral wires. (RU, patent No. 2158954, IPC Н02М 5/12, G05F 1/30, publ. 2000).

The disadvantages of the known stabilizer are large overall dimensions, lack of protection against internal short circuits.

The technical result of the invention is the reduction of overall dimensions and protection against internal short circuits.

The specified technical result is achieved by the fact that the three-phase AC voltage corrector contains three identical phase correctors, a ballast resistor shunted by a closed contact of the common contactor, a control system, each phase corrector contains a measuring transformer with primary, secondary and additional windings, the primary winding of which is connected to the corresponding phase voltage and is the first input of the phase corrector, and the secondary winding is connected to the control system, forces the first transformer with primary and secondary windings, the input and output of the secondary winding are respectively connected to the phase voltage and to the load and are the second input and the first output of the phase corrector, and the primary winding is included in the diagonal formed by serially connected closed and open contacts of the first and second contactors respectively wherein, the closed contacts are respectively connected to the input and output of the secondary winding of the power transformer, and the open contacts are combined to form a second output phase corrector and connected to a ballast resistor, and the control system controls the common, first and second contactors, characterized in that an additional circuit breaker is introduced, the first pole of which connects the input of the primary winding of one of the measuring transformers to the phase voltage, while its additional winding is connected to control system, and the second pole connects the three-phase voltage neutral to the control system, to the outputs of the primary windings of the measuring transformers, which are three im phase corrector output to a ballast common to all the phase correctors, each of which is incorporated varistors connected in parallel, respectively, the primary windings of power transformers.

The drawing shows a block diagram of a corrector for a three-phase AC voltage.

The three-phase AC voltage corrector contains three identical phase correctors 1.1, 1.2, 1.3, a ballast resistor 2, shunted by the closed contact 3.1 of the common contactor 3, a control system 4.

The phase corrector 1.1 contains a measuring transformer 5.1 with primary 5.1.1, secondary 5.1.2 and additional 5.1.3 windings, the input of the primary winding 5.1.1 is connected to the corresponding phase voltage and is the first input Bx. 1.1, and the secondary winding 5.1.2 and the additional winding 5.1.3 are connected to the control system 4, the power transformer 6.1 with the primary 6.1.1 and secondary 6.1.2 windings, the input and output of the secondary winding 6.1.2 are respectively connected to the phase voltage and to load and are the second input Bx. 2.1 and the first exit Out. 1.1 of the phase corrector 1.1, and the primary winding 6.1.1 is included in the diagonal formed by the serially connected contacts 7.1.1, 7.1.2 and 8.1.1, 8.1.2 respectively of the first 7.1 and second 8.1 contactors, while the closed contacts 7.1.1, 8.1.1 are respectively connected to the input and output of the secondary winding of the power transformer 6.1, and the open contacts 7.1.2, 8.1.2 are combined to form the second output of the Output. 2.1 phase corrector 1.1 and connected to a ballast resistor 2. Third output Output. 3.1 phase corrector 1.1 forms the output of the primary 5.1.1 winding of the measuring transformer 5.1.

The control system 4 controls the common 3, first 7.1 and second 8.1 contactors, respectively.

Circuit breaker 9, the first pole of 9.1 connects input I. 1.1 of the first phase corrector 1.1 to the phase voltage A, and the second pole 9.2 connects the neutral N of the three-phase voltage to the control system 4, to the outputs of the Outputs. 3.1, Ex. 3.2, Exit 3.3 phase correctors 1.1, 1.2, 1.3 and to the ballast resistor 2. Varistor 10.1 shunts the primary 6.1.1 winding of the power transformer 6.1.

Measuring transformer 5.1 is designed to measure the input phase voltage. In addition, the additional winding 5.1.3 of the measuring transformer 5.1 is used to generate power to the control system 4. The additional windings of the measuring transformers (not shown in the drawing) are not used in the phase correctors 1.2, 1.3. Log In 1.1 phase corrector 1.1 is connected to phase A through the pole 9.1 of the circuit breaker 9, which allows you to protect the voltage corrector from internal short circuits. Inputs 1.2, In. 2.2 and Bx. 1.3, Bx. 2.3 in phase correctors 1.2 and 1.3 are combined and are connected directly to phases B and C, respectively. Connection of outputs Outputs. 1.2, Ex. 2.2, Ex. 3.2 and Exit. 1.3, Ex. 2.3, Ex. 3.3 phase correctors 1.2 and 1.3 are identical to the connection of the corresponding outputs of the phase 1.1 corrector.

The control system 4 controls the operation modes of each of the phase correctors 1.1, 1.2, 1.3 according to the signals from the measuring transformers. When two or three phase corrector 1.1, 1.2, 1.3 are simultaneously switched to another operating mode, control system 4 determines the order of their switching on and switches on the common contactor for a short time while reconnecting contacts 7.1.1, 7.1.2 (8.1.1, 8.1.2) 3. The first (second) contactor 7.1 (8.1) is an AC voltage contactor with two independent contacts: one normally closed 7.1.1 (8.1.1) and one normally open 7.1.2 (8.1.2).

The three-phase AC voltage corrector independently adjusts the output voltage for each phase.

The corrector phase 1.1 works as follows.

Phase 1.1 corrector works in three modes: “Transit”, “Increase”, “Decrease”.

In the “Transit” mode, the first and second contactors 7.1 and 8.1 are disconnected and with their normally closed contacts 7.1.1 and 8.1.1 they connect the primary winding 6.1.1 of the power transformer 6.1 parallel to its secondary winding 6.1.2, while the output voltage (A1, N1 ) repeats the input voltage (A, N).

In the "Reduction" mode, when the voltage from the measuring transformer 5.1 exceeds the maximum threshold value of the input voltage, the control system 4 turns on the first contactor 7.1, the contact 7.1.1 is turned off and the contact is turned on

7.1.2. The beginning of the primary winding 6.1.1 of the power transformer 6.1 through a normally closed contact 8.1.1 is connected to the end of its secondary winding 6.1.2, and the end of the primary winding 6.1.1 through the included contact 7.1.2 and the normally closed contact 3.1 of the common contactor 3 is connected to zero the input voltage input (N) through the pole 9.2 of the closed circuit breaker 9. With this switching on the windings of the power transformer 6.1, the resulting voltage at the output of the phase 1.1 corrector is equal to the voltage difference applied to the primary 6.1.1 and secondary 6.1.2 rev skeins of power transformer 6.1. The magnitude of the decrease in the output voltage of the phase 1.1 corrector is determined by the transformation coefficient of the power transformer 6.1. For the reverse transition from the “Decrease” mode to the “Transit” mode, the control system 4 switches off the first contactor 7.1.

In the "Boost" mode, when the voltage from the measuring transformer 5.1 is lower than the minimum threshold value of the input voltage, the control system 4 turns on the second contactor 8.1, and the contact 8.1.1 is turned off and the contact 8.1.2 is turned on. The end of the primary winding 6.1.1 of the power transformer 6.1 through the contact 7.1.1 will remain connected to the input of the secondary winding 6.1.2, and the beginning of the primary winding 6.1.1 through the included contact 8.1.2 and the normally closed contact 3.1 of the common contactor 3 is connected to the zero input ( N) input voltage. If the windings of the power transformer 6.1 are agreed on, the resulting voltage at the output of the phase 1.1 corrector is equal to the sum of the voltages applied to the primary 6.1.1 and secondary 6.1.2 windings of the power transformer 6.1. To return from the “Increase” mode to the “Transit” mode, the control system 4 switches off the second contactor 8.1.

Due to the spread of the on / off time of the contacts 7.1.1, 7.1.2, 8.1.1, 8.1.2 of the first and second contactors 7.1, 8.1 when switching from the “Transit” mode to the “Lower” (“Increase”) mode, the contact 7.1 .1 (8.1.1) may trip, and contact 7.1.2 (8.1.2) will not turn on yet. A current circuit breaks in the primary 6.1.1 winding of the power transformer 6.1 and a high voltage is induced in it, the value of which is limited by varistor 10.1. Before turning on / off the contactor 7.1 (8.1), the control system 4 briefly switches on the common contactor 3 for a short period of time, the normally closed contact 3.1 of which opens and the ballast resistor 2 is connected to the primary winding 6.1.1 of the power transformer 6.1, which prevents the formation of an electric arc in the contacts 7.1.1, 7.1.2 (8.1.1, 8.1.2). When switching to the “Transit” mode from the “Decrease” (“Increase”) mode, when the control system 4 turns off the contactor 7.1 (8.1), an emergency situation may occur in which contact 7.1.2 (8.1.2) closes and contact 7.1. 1 (8.1.1) still remains closed. Through the contacts 7.1.1 (8.1.1), 7.1.2 (8.1.2), a through current will flow, the value of which will be limited by the ballast 2, since the contact 3.1 of the common contactor 3 will be open for the duration of the switching.

In case of a short circuit in the measuring transformer 5.1, in the primary winding 6.1.1 of the power transformer 6.1 or in the first 7.1 and second contactors 8.1, the circuit breaker 9 will open, the first pole 9.1 of which will deenergize the control system 4, and the second pole 9.2 will disconnect the neutral N from the primary windings measuring and power transformers 5.1 and 6.1.

The use of varistors reduces the overall dimensions of the entire device. Varistor 10.1 limits the voltage surge on the primary winding 6.1.1 of the power transformer 6.1, which eliminates the overall capacitance shunting the primary 6.1.1 winding of the power transformer 6.1 and RC circuit from the phase corrector to protect the contacts of the common 3, first 7.1 and second 8.1 contactors ( see prototype and analogues).

The use of one ballast resistor 2 and one common contactor 3 for three phase correctors 1.1, 1.2, 1.3 also reduces the overall dimensions of the device.

Using an additional winding 5.1.3 of the measuring transformer 5.1 allows you to generate the supply voltage of the control system 4 without using an additional power transformer.

The claimed technical result is achieved through the use of varistors, a circuit breaker 9, a ballast resistor 2, a common contactor 3 and an additional winding 5.1.3 measuring transformer 5.1.

Claims (1)

A three-phase AC voltage corrector containing three identical phase correctors, a ballast resistor shunted by a closed contact of a common contactor, a control system, each phase corrector containing a measuring transformer with primary, secondary and additional windings, the primary winding of which is connected to the corresponding phase voltage and is the first input of the phase corrector, and the secondary winding is connected to the control system, a power transformer with primary and secondary windings, One and the output of the secondary winding are respectively connected to the phase voltage and to the load and are the second input and the first output of the phase corrector, and the primary winding is included in the diagonal formed by the serially connected closed and open contacts of the first and second contactors, respectively, while the closed contacts are respectively connected to the input and output of the secondary winding of the power transformer, and the open contacts are combined to form the second output of the phase corrector and connected to the ballast and the control system accordingly controls the common, first and second contactors, characterized in that an additional circuit breaker is introduced, the first pole of which connects the input of the primary winding of one of the measuring transformers to the phase voltage, while its additional winding is connected to the control system, and the second pole connects the three-phase voltage neutral to the control system, to the output of the primary winding of the measuring transformer, which is the third output of the phase corrector, to the ballas a resistor common to all phase correctors, in each of which varistors are inserted, connected respectively parallel to the primary windings of the power transformers.

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