RU75763U1 - AC VOLTAGE STABILIZER - Google Patents

Abstract

The inventive utility model relates to electrical engineering, namely to AC voltage stabilizers, is intended for use in power supply systems to stabilize a single-phase voltage of an alternating current electric power source.

This goal is achieved in that an AC voltage stabilizer (hereinafter referred to as the stabilizer) comprising an autotransformer, a switch, a circuit breaker, a control device power supply device, power and load connection terminals, a load current sensor, a stabilizer status information display device, a load connection device consisting from an amplifier and a magnetic starter, a stabilizer control device containing a microcontroller, an output voltage sensor, a load current sensor and a blue sensor roimpulsov, the housing which houses all these elements, as well as PE connection, for determining the control input voltage and the AC voltage regulator operates using the output voltage sensor indications in the absence of an input voltage sensor.

In the stabilizer, to determine the input voltage and control the stabilizer in the on mode, the dependence between the impedances is used, when the impedance between the contacts of the input and output voltage is many times less than the impedance between the switch and the common contact, while the input voltage is very accurately equal to the output voltage measured by the output voltage sensor .

In the stabilizer for determining the input voltage and controlling the stabilizer in the on mode, the microcontroller, using the program specially laid out in it, determines from the readings of the output voltage sensor whether the readings of the input voltage are within acceptable limits and sends a command to turn on the stabilizer with the corresponding contact number of the switch key or output indication of the input voltage beyond the permissible limits gives a command to the indicator about the nature of the accident.

In the stabilizer to determine the input voltage and control the stabilizer in normal operation, the microcontroller, using the program specially laid down in it, calculates the input voltage value according to the output voltage sensor and the contact number of the included switch key.

In the stabilizer to determine the input voltage and control the operation of the stabilizer in emergency mode, the microcontroller, using the program specially laid down in it, calculates a critical value of the input voltage that is outside the permissible limits and gives the command based on the output voltage sensor and the number of one of the two extreme contacts of the included switch key to turn off the stabilizer and a command on the indicator about the nature of the accident.

In the AC voltage stabilizer in the emergency mode, as well as in the on mode, the microcontroller, using the program specially laid down in it, determines the input voltage reading from the output voltage sensor, and if it falls within acceptable limits, it sends a command to turn on the stabilizer with the corresponding switch key pin number.

Thus, the proposed controller allows you to simplify the design of the stabilizer, increase the reliability of its work and reduce the cost compared to the prototype. And the use of a regulator control device containing a microcontroller improves the reliability due to a significant reduction in the number of discrete electronic elements and the processing of a significant number of emergency situations, the measurement accuracy and the amount of displayed information are also increased, while the cost of the AC voltage regulator is reduced.

Description

The inventive utility model relates to electrical engineering, namely to AC voltage stabilizers, is intended for use in power supply systems to stabilize a single-phase voltage of an alternating current electric power source.

The closest analogue to the claimed utility model and taken as a prototype is an AC voltage stabilizer - utility model patent No. 50691, application No. 2005123427, priority 25.07.2005, containing an autotransformer, a switch, a stabilizer control device, a stabilizer control power supply device located in the housing, as well as terminals for connecting to the network and the load, circuit breaker and protective earth contact.

The control device of this stabilizer contains a microcontroller, the inputs of which are connected to the input voltage sensor, the output voltage sensor, the load current sensor and the clock sensor, and the outputs of the microcontroller are connected to the control inputs of the switch and the device for displaying information about the status of the stabilizer. This stabilizer is taken as a prototype.

The disadvantage of this stabilizer is: the complex structure of the stabilizer, high cost and unreliable operation.

The purpose of the claimed utility model is to achieve a technical result leading to - simplification of the design of the stabilizer, improving the reliability of its operation and reducing cost compared to the prototype.

Disclosure of a utility model.

The technical result is achieved due to the fact that the AC voltage stabilizer (hereinafter referred to as the stabilizer) containing an autotransformer, a switch, a circuit breaker, a control device power supply device, power and load connection terminals, a load current sensor, a stabilizer status information display device, a device

load connection consisting of an amplifier and a magnetic starter, a stabilizer control device containing a microcontroller, an output voltage sensor, a load current sensor and a clock sensor, a housing in which all of these elements are located, as well as protective earth terminals, to determine the input voltage and control the operation of the AC voltage stabilizer readings of the output voltage sensor are used in the absence of the input voltage sensor.

In the stabilizer, to determine the input voltage and control the stabilizer in the on mode, the dependence between the impedances is used, when the impedance between the contacts of the input and output voltage is many times less than the impedance between the switch and the common contact, while the input voltage is very accurately equal to the output voltage measured by the output voltage sensor .

In the stabilizer for determining the input voltage and controlling the stabilizer in the on mode, the microcontroller, using the program specially laid out in it, determines from the readings of the output voltage sensor whether the readings of the input voltage are within acceptable limits and sends a command to turn on the stabilizer with the corresponding contact number of the switch key or output indication of the input voltage beyond the permissible limits gives a command to the indicator about the nature of the accident.

In the stabilizer to determine the input voltage and control the stabilizer in normal operation, the microcontroller, using the program specially laid down in it, calculates the input voltage value according to the output voltage sensor and the contact number of the included switch key.

In the stabilizer for determining the input voltage and controlling the stabilizer in emergency mode, the microcontroller, using the program specially laid down in it, calculates a critical value of the input voltage that is outside the permissible limits and gives the command according to the output voltage sensor and the number of one of the two extreme contacts of the included switch key to turn off the stabilizer and a command on the indicator about the nature of the accident.

In the AC voltage stabilizer in the emergency mode, as well as in the on mode, the microcontroller, using the program specially laid down in it, determines the input voltage reading from the output voltage sensor, and if it falls within acceptable limits, it sends a command to turn on the stabilizer with the corresponding switch key pin number.

Figure 1 shows a functional diagram of an AC voltage stabilizer.

Figure 2 shows a simplified connection diagram of an autotransformer and an AC voltage stabilizer switch.

The stabilizer 1 contains an autotransformer 13, a stabilizer control device 2, a switch 14, a stabilizer control device power supply device 6, power and load connection terminals 8, a circuit breaker 9, a protective earth terminal 16, a load current sensor 15, an indication device 7, and a load connection device 12, consisting of an amplifier 10 and a magnetic starter 11. The control device 2 contains a microcontroller 3, an output voltage sensor 5, a clock sensor 4. These elements are placed in the housing 1. ilizator has three modes of operation:

1. The inclusion mode.

2. Normal operation mode

3. Emergency mode

Power on mode.

After turning on the circuit breaker 9, the mains voltage from terminals 8 is supplied to the autotransformer 13, to the power supply device of the stabilizer control device 6, to the switch 14, to the load current sensor 15, to the output voltage sensor 5 and the clock sensor 4. Thyristor keys 17 of the switch 14 (see Fig. 2) have a capacitance of Z ₀ = 1 / ωs, where c = 0.1 MkF, and the total resistance: Zl≈Z ₀ / k, where k is the number of keys. The output voltage sensor has a resistance of R≈300 kΩ or more. Thus, the microcontroller calculates the input voltage U _in. using to calculate the magnitude of the output voltage U _o. measured by the output sensor

voltage. Given the fact that when the load is off, (magnetic starter 11 is off), the input voltage is:

where: U _o - the value of the output voltage;

Z1 is the impedance between the connection pin U _in. (network 220 to 50 Hz.) and the connection terminal U _o. The value of Z1 is determined by the leakage currents of the switch and the impedance of the autotransformer windings connected between the network connection contact and the switch;

Z2 - impedance between the switch and pin N - common wire.

Given that Z2 is much larger than Z1 (not less than 100 times) with the load off, formula (1) takes the form:

If the magnitude of the input voltage is within acceptable limits, the control device performs the initial switching on using the load connection device 12 and the switching elements of the selected autotransformer branch in such a way that the output voltage at the load corresponds to the rated voltage.

Normal mode

All subsequent switching of the autotransformer taps is performed when the output voltage exceeds the specified limits, which determine the accuracy of stabilization of the output voltage, while the moments of these switches are no longer associated with the magnitude and shape of the input voltage.

Emergency mode

A) Initial inclusion mode. If the input voltage is out of range, the control device will not turn on

circuit breaker 6 and the switching elements of the switch and indicates on the display device the current state of the stabilizer - "network failure".

C) If the input voltage exceeds the operating range, which slightly exceeds the nominal range, the controller control device disconnects the load by turning off the magnetic starter 11 in the load connection device 12, then the switch disconnects all autotransformer taps involved in the regulation, supplying the output voltage to terminals terminated. The stabilizer goes into on mode, after normalizing the input voltage, that is, when the input voltage reaches the operating range, the control device resumes stabilizing the output voltage. In addition, the regulator control device monitors a number of emergency situations, when they occur, the output voltage to the load connection terminals is cut off. The microcontroller outputs information about emergency situations to the device displaying information about the status of the regulator.

After the initial start-up, the stabilizer goes into normal operation under the control of a microcontroller, which implements the following functions:

- measurement of the effective values of the output voltage and load current;

- calculation of the effective value of the input voltage from the value of the output voltage, taking into account the number of the tap and the load current;

- collection and analysis of signals received at the inputs of the microcontroller;

- the issuance of information to the display device about the current state of the stabilizer;

- load shedding in case of emergency with the appropriate indication;

- stabilization of the output voltage by switching the taps of the autotransformer;

- calculation of the moment of switching switching elements;

- other functions, such as measuring the temperature of power elements, turning on the fan, monitoring the health of commuting

elements, etc.

All of the above functions are implemented through the appropriate software, which is recorded in the program memory of the microcontroller during its programming.

Switching is performed after the microcontroller determines with the help of a current synchronization sensor 4 the moment the load current passes through zero. The stabilization accuracy is determined by the voltage between adjacent taps of the autotransformer, and switching at zero load current eliminates network voltage distortion.

The results of measurements of input and output voltages, power, consumed load, and other auxiliary parameters, the microcontroller outputs to the display device 7 information about the status of the controller. A high voltage regulation speed is achieved by a high measurement speed using the parameters of measurement discretization, output voltage and load current for one period of the mains voltage, and the autotransformer is switched to other taps by switch keys when the phase of the load current passes through zero, which eliminates network voltage distortion. The prior art of the claimed utility model is determined by known technical solutions.

According to the scientific, technical and patent literature, the authors are not aware of the identity of the claimed combination of features aimed at achieving the specified technical result, this technical solution does not follow clearly from the prior art, which allows us to conclude that the criterion of "novelty" of the utility model is met.

The industrial applicability of the claimed utility model of an AC voltage stabilizer is confirmed by the possibility of practical implementation by known means using known technical solutions.

Claims (6)

1. An AC voltage stabilizer comprising an autotransformer, a switch, a circuit breaker, a control device power supply device, mains and load connection terminals, a load current sensor, a stabilizer state information display device, a load connection device consisting of an amplifier and a magnetic starter, a control device a stabilizer containing a microcontroller, an output voltage sensor, a load current sensor and a clock sensor, a housing in which all of the above are located e elements and protective earth terminals, characterized in that for determining the input voltage and AC voltage stabilizer control operation using the output voltage sensor indications in the absence of an input voltage sensor. 2. The AC voltage stabilizer according to claim 1, characterized in that the dependence between the impedances is used to determine the input voltage and control the AC voltage stabilizer in the on mode, when the impedance between the input and output voltage contacts is many times smaller than the impedance between the switch and the common contact, in this case, the input voltage with high accuracy is equal to the output voltage measured by the output voltage sensor. 3. The AC voltage stabilizer according to claim 1, characterized in that for determining the input voltage and controlling the AC voltage stabilizer in the on mode, the microcontroller, using the program specially laid down in it, determines from the readings of the output voltage sensor whether the readings of the input voltage are within acceptable limits , and gives a command to turn on the stabilizer with the corresponding contact number of the switch key, or when the input voltage reading exceeds the permissible limits, it issues a command on the indicator about the accident. 4. The AC voltage stabilizer according to claim 1, characterized in that for determining the input voltage and controlling the operation of the AC voltage stabilizer in the normal mode of operation, the microcontroller, using the program specially laid down in it, calculates the value according to the output voltage sensor and the contact number of the switched switch key input voltage. 5. The AC voltage stabilizer according to claim 1, characterized in that for determining the input voltage and controlling the operation of the AC voltage stabilizer in emergency mode, the microcontroller using the program specially laid down in it according to the output voltage sensor and the number of one of the two extreme contacts of the included key The switch calculates a critical value of the input voltage that is outside the permissible limits, and sends a command to turn off the stabilizer and a command to the indicator about the accident. 6. The AC voltage stabilizer according to claim 1, characterized in that in the stabilizer in emergency mode, as well as in the on mode, the microcontroller, using the program specially laid down in it, determines the input voltage reading from the output voltage sensor, and if it is within the permissible limits, it issues a command to turn on the stabilizer with the corresponding contact number of the switch key.