SU960760A1 - Device for regulating temperature - Google Patents

Description

The invention relates to automation, in particular to devices for temperature control, and can be used in installations for the cultivation of biological objects.

A device for temperature control is known, comprising a sensor and a temperature setpoint device connected to the input of a summing amplifier, a thyristor control element connected in series with a heater, a power source, a signal conditioner and a threshold unit, the signal conditioner made in the form of two thyristor amplifiers, and a threshold unit - in the form of a series-connected memory element and an amplifier, the input of the memory element being connected to the first output of the first thyristor amplifier bodies having an input connected to the output of the summing amplifier, a second output connected to the output of the second amplifier thyristor, a thyristor connected to the actuating element, the amplifier-output of the threshold unit connected to the input of the second amplifier thyristor - (1.

The disadvantage of the device is low accuracy and high level of interference due to the operation of the device in the active part of the half-cycle of the mains voltage.

The closest to the invention in its technical essence is a device containing sensors with measuring amplifiers, a duster amplifier, generator saw voltage,. voltage comparator, thyristor pulse generator and thyristor power amplifier 12.

Disadvantages of the device - reduced

15 accuracy, stability, complex and cumbersome electronic circuit.

The aim of the invention is to improve the accuracy and simplification of the device.

20

Claims (2)

This goal is achieved by the fact that a device for temperature control, containing a temperature-sensitive bridge connected in series, an operational amplifier and a thyristor power amplifier, through the power circuit of which a heater is connected to the output of the rectifier and connected to the input of the rectifier, connected 30 with a variable source power supply, pulse power supply unit, pulse shaper and sawtooth generator, output connected to the first control input of the heat-sensitive bridge. the second control input of which is connected to the output of the binary setting device, the second output pulse generator connected to the second input of the thyristic power amplifier, contains an electronic switch connected in series with the diagonal power supply of the temperature-sensitive bridge, the control input of which is connected to the first output of the pulse voltage generator. In addition, the sawtooth generator is made in the form of a binary-decimal integrated counter connected in series with a resistive matrix, the output of which is the output of the saw-tooth generator, whose input is the control input of a binary integral counter. FIG. 1 is a block diagram of the device; in fig. 2 - voltage diagrams at various points of the device. The device contains a temperature sensor 1, included in the shoulder of the heat-sensitive bridge 2, which includes: resistors 3, 6. and operational amplifier 7-; Binary 8temperament, which includes: program binary code switches 9-11 and binary decoding resistive matrix 12, a saw voltage generator 13, consisting of a binary decimal integrated counter 14 connected to a resistive matrix 15, shaper 16 pulses consisting of. two logical inverters 17 and 18, a pulsed power supply unit 19, providing a pulse voltage of 100 Hz to the driver 16 and a constant supply voltage to all other units of the device; a thyristor power amplifier 20 consisting of a two-input surgical element 21 connected to the input of an opto-coupler 22, the output of the latter connected to the input of a transistor 23, the power supply to the thyristor 23 and to the heater 24 is supplied from the rectifier 2 electronic switch 2 & impulses from the imager 16. The device operates as follows. The pulse signal (Fig. 2a) is fed to the input of the imaging device 1b pulses. From the output of the logical inverter 17, the pulses (Fig. 26) are fed to the inputs of the integral binary-decimal counter 14 and the key 26. The counter 14 divides the frequency of the pulses into ten. The signals from the outputs of counter 14 through the re-active matrix 12 are converted into a saw-step voltage with ten steps (Fig. 2c). The key 26 commutes with a frequency of 100 Hz the supply voltage to the temperature sensor 1 and the setting device 8 through limiting resistors 3 and 4. - Due to this, the sensor 1 is powered by current pulses of a frequency of 100 Hz with a duration of 1 ms (Fig. 2). However, the permissible average power dissipation, as in the case of direct current supply, several times increases the value of the useful signal taken from sensor 1. This dramatically increases the stability and accuracy of the entire device. The signal from sensor 1 is fed to the inverted input of the operational amplifier 7. The second input of the operational amplifier 7 receives signals from the setpoint temperature 8 and from the generator 13. The signals are compared using the operational amplifier 7, which performs the role of a comparator. The waveform is shown in FIG. 2d, while the section t corresponds to overheating, and the section t to non-heating. The signal from the output of the operational amplifier 7 is fed to the first input of the logic element 21 of the thyristor power amplifier 20. The second input of the ophic element 21 receives voltage gating pulses from the imaging device 16. The pulses from the output of the logic element 21 (Fig. 2e) are fed to the input of the optocoupler 22, the output of which is connected to the input of the thyristor 23. The thyristor is triggered on underheating, at the beginning of each half-period (zero phase) pulses (Fig. 2e). A current flows through the heater 24 (Fig. 2 g), the number of pulses of which is proportional to the change in the signal from the temperature sensor 1, and the slope of this change is controlled by means of a resistor 5, which makes it possible to optimize the circuit for any control object. Due to the fact that the device contains an electronic key 26, and the sawtooth generator is made in the form of a binary-decimal integrated counter connected to a resistive matrix, it was possible to increase the accuracy and simplify the circuit of the device. Claim 1. A temperature control device comprising a thermosensitive bridge connected in series, an operational amplifier and a thyristor power amplifier, through whose power circuit a heater is connected to the output of the heater and connected in series with the rectifier input connected to an alternating voltage source power supply unit, pulse power supply unit, pulse shaper and sawtooth generator, output connected jc to the first control input of the thermal sensor The second bridge, the second control input of which is connected to the output of a binary sensor, the second output of the pulse shaper is connected to the second input of the thyristor power amplifier, which is so that, in order to improve the accuracy and simplify It contains the connected pic. Then, with the diagonal of the power supply of the temperature-sensitive bridge, the electronic key, the control input of which is connected to the first output of the impulse bar. 2. A device according to claim 1, characterized in that the saw-tooth voltage generator is made in the form of a binary-decimal integrated counter connected in series with a resistive matrix, the output of which is the output of the saw-voltage generator, the input of which is a binary control input - a domestic integrated counter. Sources of information taken into account in the examination of 1 .. USSR author's certificate 613302, cl. G 05 D 23/19, 1975. 2. Patent CWA 3584291, cl. 2323-18, published. 1971 (prototype). lllllllll tppp UULJLJJJJJLJLJIJJIJJ ti LL well Phage1 ppp t2 Alla