EA016468B1 - Control device for consumption power in ac networks - Google Patents

Abstract

The present invention relates to electrical engineering, in particular the power limiter for use in networks with a voltage of 0.4 kV, is intended for automatic control circuits off "Load" in excess of a threshold level of power consumption and continuous monitoring of the parameters of the mains. EFFECT: increased speed of operation of protection in the three-phase AC networks, the ability to disable the "Load" from the power supply with an increase in power consumption than the set value and the auto-connect "Load" after elimination of the causes of congestion.A control device is characterized in that the computing unit 4 contains a microprocessor device, A2, and the measuring unit 3 is provided with a means of converting the parameters A1 input voltage and current signals into digital code and is adapted to transmit a digital code on a microprocessor-based device A2 computing unit 4.

Description

The invention relates to the field of electrical engineering, in particular to power limiters for use in electrical networks with voltage up to 0.4 kV, is intended for automatic control of disconnection of load circuits when exceeding the threshold value of the level of power consumption and continuous monitoring of the supply network (protection against voltage surges, violation of the order of the phase sequence, the breakage of the neutral wire and short circuit).

Known devices for protecting consumers from overloads and short circuits [1, 2, 3]. So, the automatic high-speed switch [1] contains a frame, movable and fixed contacts, holding an electromagnet with a magnetic circuit and an armature mounted on a common axis. The switch is equipped with a two-arm lever, one end of which is connected to the common axis of the magnetic circuit and the anchors of the holding electromagnet. The other end of the two-shouldered lever is connected to the anchor of the switching mechanism and is additionally equipped with an earring, one end of which is pivotally mounted in the frame support, and the other end is pivotally connected to the rod connecting the armature and the movable contact. The end of the movable contact, opposite to its end, intended for connection with a fixed contact, is pivotally connected by an additional rod to the anchor of the holding electromagnet. The main disadvantage of the device is its low speed.

A device for protecting the consumer from abnormal voltage and current in AC networks with an amplitude limiter [2] contains two threshold elements and an actuator, which is also a protective device. The device is also equipped with a measuring unit, and the threshold elements when the voltage of the network is higher or lower than the specified levels through the measuring unit provides a trip signal to the timer. An optocoupler LED, a thermistor-temperature sensor, a current transformer connected to a timer and connected in series with the actuator are connected to the control output of the timer. The executive body consists of two on-off field-effect transistors and protective diodes. The sources of field-effect transistors are connected to a common wire of the control circuit, which includes a parallel-storage capacitor and a zener diode connected through a quenching resistor to a rectifier of the mains voltage on the diode. The gates of field-effect transistors are connected through a current-limiting resistor and a non-polar zener diode in parallel with the consumer and through an optocoupler photodiode to a common control circuit wire. The measuring unit gives a signal to disconnect the consumer from the network when the load current measured by the current transformer increases, or when the temperature of the field-effect transistors is measured by a thermistor-temperature sensor. The disadvantage of this device is the lack of adjustment of the delay time for switching it on for consumers with various technical parameters, as well as protection against current overloads and overheating of power transistors, which reduces the functionality and its reliability of the device as a whole.

Closest to the proposed invention is a device for protecting the consumer from abnormal voltage and current in AC networks with an amplitude limiter, which is chosen as a prototype [4]. The device contains two threshold elements and an executive body, which is simultaneously protective. The device is equipped with a measuring unit, and threshold elements when the voltage of the network is higher or lower than the specified levels through the measuring unit give a trip signal to the timer. The LED of the optocoupler, a thermistor-temperature sensor and a current transformer are connected to the control output of the timer. The latter is connected to a timer connected in series with the actuator, which consists of two on-line bipolar transistors and protective diodes, the emitters of the bipolar transistors are connected to a common control circuit wire, which consists of a storage capacitor and a zener diode connected in parallel through a quenching resistor with a rectifier of the mains voltage on the diode, and the bases of bipolar transistors are connected through a current-limiting resistor and a non-polar zener diode parallel to the consumer and through the photodiode of the optocouplers to the common wire of the control circuit, while the measuring unit provides a signal to disconnect the consumer from the network when the load current is measured by the current transformer or when the temperature of the bipolar transistors is measured by the thermistor-temperature sensor. The disadvantage of this device is the low speed response of the protection, the low accuracy of measuring voltage, current and power, as well as the inability to use external current transformers to increase the value of the controlled power.

The aim of the invention is to increase the speed of protection in three-phase AC networks, the ability to disconnect the load from the power supply when the power consumption rises above the set value and automatically connect the load after eliminating the causes of overload.

The goal is achieved in that in a device for monitoring power consumption in alternating current networks, comprising measuring and computing units, control and power units, as well as an executive output unit, functionally interconnected, according to the invention, the computing unit further comprises a microprocessor device, and the measuring unit is provided with means converting the parameters of the input signals of voltage and current into a digital code and is made with

- 1 016468 the ability to transmit a digital code to a microprocessor device of a computing unit.

The control unit is configured to set the operation algorithm of the microprocessor device of the computing unit, the time parameters of disconnection and inclusion of the load and the value of the power level.

The invention is illustrated by drawings in FIG. 1-3.

In FIG. 1 shows a block diagram of a device;

in FIG. 2 - circuit diagram;

in FIG. 3 - the appearance of the device.

In case 2 of device 1 (Fig. 3), a measuring unit 3 is mounted with means A1, made on the basis of an analog to digital signal converter, for processing input signals by converting the input voltage and current signal parameters to a digital code with limiting resistors K1, K2, K3 , built-in current transformers T1, T2, T3, connectors ХР1 and ХР2, microprocessor device A2 of computing unit 4, control unit 5, executive (output) unit 6, power supply 7. Power supply (Fig. 2) wires b1, b2, b3 three phase se and mounted in internal openings torroidalnyh measuring current transformers T1, T2, T3 unit 3 for processing the input signals. Current transformers T1, T2, T3 are not electrically connected to the three-phase power supply L1, L2, L3. The XP1 connector of the input signal processing unit 3 is used to connect an electromechanical counter (not shown in the drawing) for measuring the current power consumption. The presence or absence of voltage at the XP2 connector indicates the direction of power consumption (the load itself consumes power or transfers it to the power circuit with the reactive nature of the load).

The principle of operation of the device 1 is based on the continuous calculation of the value of power consumption and comparing it with a given value. The following signals are received in the measuring unit 3 for processing input signals (Fig. 2): a signal proportional to the voltage of the power supply network (through the limiting resistance K1-K3), and a signal from measuring current transformers T1-T3 proportional to the current consumed by the load. The incoming signals by means of an A1-analog-to-digital converter are converted into a digital code in the measuring unit 3 and transmitted to the microprocessor device A2, made on the basis of the microcircuit, computing unit 4, where the actual value of the power consumption is calculated. The switches K4, K5 and 81 of the control unit 5 determine the algorithm of the computing unit 4:

temporary parameters of disconnection and switching on of the Load (adjustment of the disconnection time during overload from 2 to 180 s; adjustment of the reclosing time from 15 s to 10 min);

power level at which the load is disconnected.

Computing unit 4 (Fig. 2) with microprocessor devices A2 through resistors K6, K7 and control transistors T ₆ and T _{7 of the} executive (output) block 6 (Fig. 1), respectively, is connected with the executive bodies - relays K1 and K2.

In addition to the main function of monitoring and limiting power, device 1 can carry out load disconnection when the voltage in the supply network rises above 260 V in 0.1 s, as well as when it drops below 160 V in 10 s and is restarted 10 seconds after restoration; nominal value of power supply parameters (voltage relay function in each phase);

protection of the supply network against overcurrent and short circuit in the Load (the current value at which the Load is switched off is calculated based on the set power value, when this value is exceeded by 10 times, the Load is disconnected in a period of not more than 0.1 s);

Load disconnection in the event of a zero wire break in 0.1 s;

phase rotation control and voltage asymmetry between phases (in three-phase supply networks);

protection of power circuits from cyclic overload (blocking the load on for 10 minutes when overloading more than 10 times in power for a time of 10x1, where 1 is the time of repeated switching on).

The power threshold is calculated in two ways:

option - in phases, the installed capacity is divided by 3, option - in total, defined as the sum of the capacities in phases, and also in phases - the installed capacity times 2/5 (the power is divided by 3 and 20% of the division by 3 is added to the result).

Option 1 is preferable to use at uniform Loads on separate phases. Option 2 allows 20% overload in individual phases (i.e., load skew). If in real conditions it is difficult to ensure a uniform phase load, then the second option for calculating power is preferable.

In the process of operation of device 1 (Fig. 3), the power level is monitored, and as soon as the power consumed by the Load exceeds the threshold value set by the control unit 5, the microprocessor computing device 4 gives a signal to disconnect the Load for the time specified by the switches of the control unit 5. Power supply 7 converts the voltage from the power supply b1, b2,

- 2 016468

B3 in a series of DC voltages necessary for the operation of the main units of the device 1.

Power adjustment is made stepwise in the range from 5 to 35 kW (9 values) with the presence of a technological mode, when the power adjustment is forcibly turned off, but the load remains connected. The range of controlled currents is from 3 to 100 A (it may increase when using external current transformers). The error in measuring voltage and power is 3%, current - 1%. It is possible to carry out measurements with an accuracy of 0.1%, which is determined by the accuracy class of the mounted components used in the measuring unit 3 of the input signal processing.

The device 1 provides an output for connecting an external alarm (not shown in the drawing) to warn the consumer about exceeding the value of the power allocated to him. As soon as the level of power consumed by the load exceeds the threshold value set by the control unit 5, the microprocessor computing device 4 provides a signal to the relay K1 with a frequency of 1 Hz (within 80% of the set load disconnection time). During the remaining 20% of the time before the load is switched off, relay K1 will be switched on continuously. This will warn the consumer about disconnecting him from the power supply after a period of time set on the control unit 5. Also, this signal can be used in automation and control systems, in computer networks for collecting and processing data, etc. After a specified time, the microprocessor load is disconnected the computing device 4 provides a signal to the relay K2, which disconnects the load for the time specified by the control unit 5. Re-automatic connection of the load is possible only after eliminating the cause Booting.

The developed device for monitoring power consumption is also used to protect against unauthorized connection of unauthorized consumers to the power network, to control power consumption when introducing limits on electricity consumption, etc.

Information sources.

1. VI No. 2296386 C1, 2007.03.27.

2. VI No. 2231190 C2, 2004.06.20.

3. Equipment for low voltage distribution networks for currents from 0.5 to 125 A. 5> s1shs1bsg E1es1ps. MiSh 9 Met1sh Smallpox. Catalog 2006.

4. VI No. 2223583 C2, 2004.02.10 (prototype).

Claims (2)

CLAIM 1. A device for controlling power consumption in AC networks, containing functionally interconnected measuring and computing units, control and power units, as well as an executive output unit, characterized in that the computing unit further comprises a microprocessor device, and the measuring unit is equipped with a parameter conversion tool input signals of voltage and current into a digital code and configured to transmit a digital code to the microprocessor device of the computing unit . 2. The device according to claim 1, characterized in that the control unit is configured to specify the algorithm of the microprocessor unit of the computing unit, the time parameters for switching off and on the Load and the power level values.