RU2032209C1 - Temperature controller - Google Patents

Abstract

FIELD: automatic control devices. SUBSTANCE: temperature controller has pulse generator 1, measuring bridge 2, recording unit 3, power element 4, temperature indicator 5, and load 6. Voltage regulator diode 10, resistor 9, and transistor 8 shape 100-Hz pulses synchronized by supply mains as sine wave crosses zero. EFFECT: improved temperature control accuracy, eliminated supply mains and radio interferences, simplified design. 2 dwg

Description

 The invention relates to automatic control and can be used to maintain temperature in both industrial and domestic facilities, as well as in electromechanical systems, temperature-dependent.

 A known temperature controller comprising a sensor and a temperature setter, the outputs of which are connected respectively to the first and second inputs of a differential amplifier, a comparator, the output of which is connected to the input of the actuator, an inverting amplifier, an analog multiplexer and an integration unit, the output of the differential amplifier is connected to the first inputs of the comparator and an analog multiplexer, as well as with the input of an inverting amplifier, the output of which is connected to the second input of the analog multiplexer, in the output of which through the integration unit is connected to the second input of the comparator, the output of which is connected to the control input of the analog multiplexer [1].

 A device for regulating temperature is known, comprising a series-connected temperature setter, a regulator and an actuator unit, a thermoelectric converter connected by a single output through the first input of the switch to the input of the measuring transducer, a manual setting unit for the regulation unit connected by an output to the second input of the regulator, the third input of which is connected to the output of the measuring transducer and the input of a two-level comparator, a single vibrator and a voltage reference source, at m the input of the single-vibrator is connected to the output of the two-level comparator connected to the start input of the manual unit for setting the control unit, and the output is to the control input of the switch, the second input of which is connected to the first output of the reference voltage source, the second output of which is connected to the second output of the thermoelectric converter by a common bus [ 2].

 The disadvantages of the known devices are low reliability and insufficient accuracy of temperature maintenance, due to the presence of complex structural and circuitry solutions. In addition, such devices are sources of network and radio interference due to the lack of synchronization of the actuating power element by mains voltage.

 Closest to the proposed device is a temperature control device containing the first and second thyristors connected in opposite-parallel and connected in series with the load element in an alternating current network, a bridge rectifier, a pulse generator with a thermistor, decoupling diodes, suppressor resistors, a third and the fourth thyristors, with the bridge rectifier connected to the input diagonal parallel to the first and second thyristors, and the output diagonal to the power input and the common bus pulse, the output of the pulse generator through decoupling diodes connected to the control electrodes of the first and second thyristors, the cathodes of which are connected to the anodes of the third and fourth thyristors, connected by the cathodes to the common bus of the pulse generator, and the anodes of the first and second thyristors are connected through quenching resistors to control electrodes of the third and fourth thyristors, respectively.

 In the prototype device, synchronization with the mains voltage occurs sequentially, first the third thyristor opens and after a certain period of time the control pulse of the current from the generator comes to the control electrode of the first thyristor, which leads to incomplete power output, since the first power thyristor is delayed in time. A similar process occurs with the second power thyristor. As a result of the half-wave of alternating voltage, there is a cutoff angle, which creates network and radio interference.

 In addition, this device has low accuracy of temperature control due to a change in the voltage supply of the pulse generator, since the voltage at the input diagonal of the bridge rectifier with closed and open first and second thyristors varies from 200 V to 2 V.

 At the same time, the presence of the first and second thyristors in the circuit connected in opposite parallel leads to the need to use two separate radiators to dissipate high power, and thus increases the dimensions of the device.

 The aim of the invention is to improve the accuracy of temperature control, the exclusion of network and radio interference and increase reliability by simplifying the circuitry and design of the device.

 For this, a temperature control device containing a power element, a bridge rectifier, a pulse generator and a sensor is equipped with a measuring bridge, a control device made on two transistors and a thyristor optocoupler, a second bridge rectifier and a heating indicator made on the LED, while the power element is made on the triac, the pulse generator is on the transistor, the base of which is connected to one terminal of the base resistor, the anode of the separation diode, the cathode of the zener diode and with a positive the output of the first bridge rectifier, one input terminal of the first rectifier through two series-connected resistors and its other input terminal are connected to the first and second terminals of the AC network, the other output terminal of the first rectifier, the zener diode anode and the second terminal of the base pulse generator resistor are connected to a common bus, the emitter of the transistor of the pulse generator is connected to the cathode of the separation diode, with a positive terminal of the capacitor and with the emitter of the second transistor of the recording device, the base of which is connected to the collector of the first transistor of the recording device, and the emitter and the base of the latter are connected to the output of the measuring bridge, two thermistors are included in the opposite shoulders, and a reference resistor and a regulator in the other two opposite shoulders, the input of the measuring bridge is connected to the collector of the pulse generator transistor , the collector of the second transistor of the recording device through a limiting resistor is connected to the input of the thyristor optocoupler, the output of the thyristor optocoupler is included in the diagonal of the second bridge rectifier, one input terminal of which is connected to the triac anode, with one load terminal, the heating indicator LED cathode and the protective diode anode parallel to the LED, the cathode of which is connected through the limiting resistor to another load terminal and is connected to the first terminal of the supply network and the other input terminal of the second bridge rectifier is connected to the control electrode of the triac, the cathode of which is connected to the second terminal of the supply network.

 The execution of the pulse generator on the transistor in the device, the base of which is connected to the zener diode cathode and the resistor, and the transistor base is supplied with power from the first bridge rectifier, creates the condition for the pulse generator to open the transistor at the moment the sinusoidal voltage of the network passes through zero, which allows you to open the power element, supplying the load, at the time of a minimum increase in the amplitude of the sinusoidal power voltage, therefore, a sinusoidal voltage is created at the load and, therefore, The formation of network and radio interference is completely excluded.

 The presence of a measuring bridge in the device, the input of which is connected to the collector of the transistor of the pulse generator, with two thermistors included in the opposite arms of the bridge, and an exemplary resistor and temperature regulator in the other two opposite arms, can significantly reduce the dissipated power on the thermistors and, therefore, reduce measurement error.

 The use of a measuring bridge with two thermistors in opposite shoulders leads to a doubling of the mismatch, which improves the accuracy of measuring the temperature of the object.

 The presence in the temperature control device of a recording device made on two transistors and a thyristor optocoupler, as well as a second bridge rectifier, provides a sufficient gain of the recording device to create a rated current control power triac, which allows you to completely give power to the load, and also to exclude the influence of the power part to the measuring part of the thermostat and, therefore, to ensure increased accuracy of regulation.

 The use of five active elements in a temperature control device: a generator on one transistor, a recording device on two transistors and an optocoupler, and a power element on a triac made it possible to simplify the device circuit, its design, as well as reduce the requirements for the used components and significantly increase the reliability of the device.

 In FIG. 1 shows a circuit diagram of a device; figure 2 - diagrams of the temperature controller.

 The proposed device for temperature control comprises a pulse generator 1, a measuring bridge 2, a recording (control) block 3, a power element (triac) 4, a heating indicator 5, a load 6, a first bridge rectifier 7, while the pulse generator 1 consists of a transistor 8, the base of which is connected to the resistor 9, the cathode of the zener diode 10, the positive output of the bridge diode rectifier 7 and the anode of the isolation diode 11. The emitter of the transistor 8 is connected to the cathode of the isolation diode 11 and to the plus of the capacitor 12. Negator The first output of the bridge diode rectifier 7 is connected to the anode of the zener diode 10, the resistor 9, with the minus of the capacitor 12, forming a common bus of the measuring part of the thermostat.

 Thus, the power is supplied from a bridge rectifier 7, which is connected with variable diagonal through the limiting resistors 13 and 14 to the power supply terminals 15 and 16 of the variable network 220 V, 50 Hz.

 The collector load of the pulse generator 1 is a measuring bridge 2, the supply diagonal of which is connected to a common bus. Thermistors 17 and 18 are included in the opposite shoulders of bridge 2, and a model resistor 19 and temperature switches are included in the other two shoulders: coarse — resistor 20 and accurate — resistor 21. The diagonal of bridge 2 with points E and B is a measurement. The recording unit 3 consists of a first input transistor 22, which is connected by an emitter-base junction to the measuring diagonal of the bridge 2. The collector of the transistor 22 is connected to the base of the second transistor 23, the emitter of which is connected to the plus of the capacitor 12. The collector of the transistor 23 is connected to the input through a limiting resistor 24 thyristor optocoupler 26. Resistor 25, connected between the collector of transistor 23 and the base of transistor 22, forms a feedback. This ends the measuring and recording part of the temperature control device. The power element 4 is made on the triac 27, the control circuit of which includes the output of the second bridge rectifier 28. One input of the variable diagonal of the bridge rectifier 28 is connected to the anode of the triac 27, and the second to the control electrode of the triac 27. The output part of the positive diagonal of the bridge rectifier 28 is included thyristor optocoupler 26, respectively, the anode to the plus and the cathode to the minus. The cathode of the triac 27 is connected to the supply terminal 16, and the anode to the load 6, the second end of the load 6 is connected to the supply terminal 15.

 The heating indicator 5 consists of an LED 29, the cathode of which is connected to the anode of the triac 27, and a protective diode 30 is connected counter-parallel to the LED 29, the cathode of which is connected through the resistor (limiting) 31 to terminal 15.

 The device operates as follows.

 The input sinusoidal voltage of the network, limited by current by resistors 13 and 14 and rectified by the first bridge rectifier 7, is limited by the voltage of the zener diode 10 and is supplied to the base of the transistor 8 (Fig.2b). Trapezoidal pulses through the diode 11 charge the capacitor 12, which is the power source for the measuring and recording parts of the circuit. At the moment of existence of the trapezoidal pulse, the transistor 8 is closed, and only when the trapezoidal pulse drops to zero, the base current of the transistor 8 arises, which opens for a short period of time (Fig. 2B). The measuring bridge 2 is powered by these pulses. Short current pulses flow along the two branches of the measuring bridge through resistors 20 and 21 and the thermistor 18, as well as through the thermistor 17 and resistor 19. A voltage drop occurs in the measuring diagonal of the B / E bridge relative to the common bus. The thermistors 17 and 18 are located in the temperature control zone, and when the regulator made on the resistors 20 and 21 is set so that the voltage drop across the thermistor 18 is greater than the voltage drop across the resistor 19, then the temperature of the control object is lower than the set one, while the base potential above the emitter potential and transistor 22 opens. There is a base current of the transistor 23, which flows along the chain: plus of the capacitor 12 - emitter-base of the transistor 23 - collector-emitter of the transistor 22 - resistor 19 - minus the capacitor 12. The transistor 23 opens and through the feedback resistor 25 an avalanche-like opening of the transistor 22 occurs.

 The collector current of the transistor 23 flows through the limiting resistor 24 and the input part of the thyristor optocoupler 26 (Fig.2g). The positive diagonal of the second bridge rectifier 28 includes a part of the thyristor optocoupler 26, which opens in accordance with the input part (fig.2d).

 Through the control electrode of the triac 27 current flows in the phase corresponding to the applied mains voltage (Fig.2E). As a result, the triac 27 opens and the load 6 is connected to the terminal 15 of the mains supply voltage.

 The current flows: input terminal 15 - load 6 - triac 27 - input terminal 16 (fig.2zh).

 The regulation object is heating up. The voltage drop across the load 6 creates a current through the limiting resistor 31 and the LED 29, which indicates that there is heating.

 When the control object is heated, the thermistors reduce their resistance, while the voltage drop across the thermistor 18 decreases and increases at the resistor 19. The emitter potential of transistor 22 becomes higher than the base potential, transistor 22 closes, therefore, transistor 23 does not open, and through the input part of the thyristor optocoupler 26 no current flows and its output does not open (fig.2d, e). There are no control pulses on the control electrode of the triac 27 (Fig.2e), therefore, the triac 27 is closed, the load 6 is de-energized, and no current flows through the LED 29. The LED does not light up, indicating that the temperature of the control object has reached the set value.

Thus, the proposed schematic of a device for temperature control ensures high (up to ± 0,3 ° ^C) Temperature stability while enhancing the reliability of the temperature control products treatment regimen that leads to a substantial improvement of product quality, which requires the constant temperature mode.

Claims (1)

 A TEMPERATURE CONTROL DEVICE comprising a temperature sensor, a first bridge rectifier, a pulse generator, a power element and a load, characterized in that the device is equipped with a recording unit made of two transistors, two resistors and a thyristor optocoupler, a second bridge rectifier and made on the LED protective a diode and a resistor with a heating indicator, while the power element is made in the form of a triac, the temperature sensor is made in the form of a measuring bridge, in two opposite arms of which о thermistors are included, and in the other two opposite arms there is an exemplary resistor and a setter, respectively, and the pulse generator is made on a transistor, a base resistor, an isolation diode, a zener diode, a capacitor, a first bridge rectifier and two resistors, and the base of the pulse generator transistor is connected to one output the base resistor, the anode of the separation diode, the zener diode cathode and with the positive output of the first bridge rectifier, one input terminal of the first bridge rectifier through two connected resistor, and its other input terminal is directly connected to the first and second terminals of the AC network, the other output terminal of the first bridge rectifier, the zener diode anode, the corresponding capacitor terminal and the second terminal of the base pulse generator resistor are combined with a common bus, the pulse generator transistor emitter is connected with the cathode of a separation diode, with a positive terminal of the capacitor and the emitter of the second transistor of the recording unit, the base of which is connected to the collector rum of the first transistor of the recording unit, and the emitter and base of the last connected to the output of the measuring bridge, the input of the measuring bridge is connected to the collector of the transistor of the pulse generator, the collector of the second transistor of the recording unit through the first resistor is connected to the base of the first transistor of the recording unit, and through the second resistor to the input thyristor optocoupler, the output of the thyristor optocoupler is included in the diagonal of the second bridge rectifier, one input terminal of which is connected to the anode of the triac, with one pin the load cathode, the cathode of the heating indicator LED and the anode of the protective diode connected in parallel with the LED, the cathode of which is connected through a resistor to another load terminal and connected to the first terminal of the supply network, and the other input terminal of the second bridge rectifier is connected to the control electrode of the triac, the cathode of which is connected to second mains terminal.

Images