RU204204U1 - Temperature regulator - Google Patents

Abstract

The utility model relates to the field of electrical engineering, electronics and automatic temperature control and can be used to adjust and maintain the heating temperature of soldering irons at a given level. The technical result is to increase the reliability of the temperature controller and increase the accuracy of temperature control of the soldering iron. The technical result is achieved due to the fact that a temperature controller containing a comparator, a temperature setting device, a positive voltage stabilizer, a heater and a thermocouple connected in series, while additionally equipped with a thermocouple signal amplifier, the output of which is connected to the input of the comparator, an integral timer, the input of which is connected to the output of the comparator, and its output is connected to the input current amplifier, the output of the current amplifier is connected to an electronic switch on an optothyristor, an AC bridge rectifier, to the input of which the AC supply voltage is supplied, and its positive output is connected to an electron to the input of the positive voltage stabilizer and the capacitor connected between the input of the positive voltage stabilizer and the negative output of the AC bridge rectifier.

Description

The utility model relates to the field of electrical engineering, electronics and automatic temperature control and can be used to adjust and maintain the heating temperature of soldering irons at a given level.

Known temperature controller (RF patent No. 2263339, IPC G05D 23/20, publ. 27.10.2005, bull. No. 30), consisting of a heater, a sensor and a temperature sensor connected to the inputs of the amplifier, key, voltage converter with the first transformer and the second transformers, pulse generator, mains voltage rectifier, filter and heater.

The disadvantage of this temperature regulator is the difficulty in setting up and insufficiently good repeatability in production, which is due to the construction of a voltage converter according to an autogenerating circuit.

Known temperature controller (RF patent No. 2239864, IPC G05D 23/19, publ. 10.11.2004, bull. No. 31), consisting of a temperature sensor and a temperature sensor connected to the inputs of the first amplifier, thyristor switch connected to the output of the heater, the second amplifier, output connected to the control electrode of the thyristor, resistor and diode.

The disadvantage of this temperature controller is the difficulty in setting up and the ability to work only from an alternating voltage source.

Known heating temperature regulator (RF patent No. 2105345, IPC G05D 23/19, publ. 20.02.1998), consisting of a temperature setpoint, a comparison element, a temperature sensor, a sample-storage element, a pulse-width modulator, a sync pulse generator, a one-shot, an element And, heater and switch.

The disadvantage of this temperature controller is the significant complexity and insufficient accuracy of temperature control.

The closest to the useful model is the simplest T12 soldering station (The simplest T12 soldering station. Access mode: https://handmade32.ru/elektronika/prostejshaya-payalnaya-stantsiya-na-zhalah-t12/. - Heading with screen), consisting of a comparator, a temperature sensor, a resistor, a capacitor, a resistor divider, a second comparator, a positive voltage stabilizer, an amplifier, an electronic switch on a field-effect transistor with a p-type channel, a heater and a thermocouple. This device is designed to work with soldering irons equipped with a T12 tip, the heater of which is connected in series with a thermocouple.

The disadvantage of this simplest soldering station on T12 tips is insufficiently high reliability of operation and low control accuracy in static and dynamic modes due to the low level of the thermocouple signal, which is 6 mV at a temperature of 300 ° C, which is at the level of the minimum input voltage of the comparator, and also due to the influence of noise on the input circuits of the temperature controller, induced in the measuring circuit by the heater current.

The problem to be solved by the claimed utility model is to develop a temperature controller that provides high accuracy of temperature control and low sensitivity to interference.

The technical result is an increase in the reliability of the temperature controller and an increase in the accuracy of the temperature control of the soldering iron.

The technical result is achieved due to the fact that a temperature controller containing a comparator, a temperature setter, a positive voltage stabilizer, a series-connected heater and a thermocouple, while additionally equipped with a thermocouple signal amplifier, the output of which is connected to the input of the comparator, an integral timer, the input of which is connected to the output comparator, and its output is connected to the input of the current amplifier, the output of the current amplifier is connected to an electronic switch on an optothyristor, an AC bridge rectifier, to the input of which an AC supply voltage is supplied, and its positive output is connected to an electronic switch on an optical thyristor, and through a diode - to the input of the positive voltage stabilizer and a capacitor connected between the input of the positive voltage stabilizer and the negative output of the AC bridge rectifier.

The essence of the proposed temperature controller is to introduce a thermocouple signal amplifier and an integral timer into it, which forms a pulse of a fixed duration to control an electronic switch made on an optothyristor, which will improve the accuracy of temperature control and increase the reliability of the temperature controller when powered from an AC source.

FIG. 1 shows a block diagram of a temperature controller. FIG. 2 shows the voltage diagrams at the characteristic points of the temperature controller circuit.

The block diagram of the temperature controller (Fig. 1) contains a thermocouple signal amplifier 1, a temperature setpoint 2, a comparator 3, to the inputs of which signals are supplied from the outputs of the amplifier 1 and a temperature setpoint 2, an integral timer 4 controlled by the output signal of the comparator 3, a positive voltage stabilizer 5 , current amplifier 6, the input of which is connected to the output of the integral timer 4, and the output is connected to the input of the electronic switch on the optothyristor 7, and the electronic switch on the optothyristor 7, the heater 8 and the thermocouple 9 are connected in series and connected between positive (+) and negative (- ) by the outputs of the AC bridge rectifier 10. The input of the thermocouple signal amplifier 1 is connected to the output of the electronic switch on the optothyristor 7. The supply voltage is smoothed by the filter formed by the diode 11 and the capacitor 12, and is fed to the input of the positive voltage stabilizer 5, the output voltage of which is intended to supply all temperature controller blocks.

The temperature controller works as follows.

The thermocouple signal amplifier 1 amplifies the output voltage of the thermocouple 9, which is fed from the output of the thermocouple signal amplifier 1 to the first input of the comparator 3, the second input of which is supplied with voltage from the temperature sensor 2. FIG. 2, a shows the amplified voltage of the thermocouple signal at the output of the signal amplifier of the thermocouple 1 (continuous line), and the voltage of the temperature sensor 2 (dashed line). Comparator 3 compares these voltages, and in the case when the voltage of the signal of the thermocouple 9 becomes less than the voltage of the temperature sensor 2 (times t ₁ and t ₃ ), a low voltage level appears at the output of the comparator 3, and at this moment the integral timer 4 is started, at the output of which a voltage pulse of fixed duration t _and = t ₂ - t _{1 is formed} (Fig. 2, b), which is amplified by the current amplifier 6 (Fig. 2, c), the output current of which flows through the control circuit of the output switch on the optothyristor 7, and opens it.

In this case, from the positive (+) output of the bridge AC rectifier 10 through the open electronic switch on the optothyristor 7, through the heater 8 and the thermocouple 9 connected in series with it to the negative (-) output of the bridge AC rectifier 10, current begins to flow (Fig. 2, d, time periods t ₁ - t ₂ , t ₃ - t ₄ ). During the time of the open state of the electronic switch on the optical thyristor 7 at the output of the signal amplifier of the thermocouple 1 there are voltage pulses, (Fig. 2, a), the amplitude of which is equal to the output voltage of the positive voltage stabilizer 5. After the end of the pulse at the output of the integral timer 4, the electronic switch on the optical thyristor 7 is closed, and the current from the positive (+) output of the bridge AC rectifier 10 through the electronic switch on the optothyristor 7, the heater 8 and the thermocouple 9 connected in series with it is terminated. Since the thermocouple 9 is heated, at the input of the signal amplifier of the thermocouple 1 there is a voltage from the thermocouple 9, proportional to the temperature of the heater 8 (Fig. 2, a, time periods t ₀ - t ₁ , t ₂ - t ₃ ).

When the voltage of the thermocouple 9 from the output of the signal amplifier of the thermocouple 1 is less than the voltage of the temperature setpoint 2 (times t ₁ and t ₃ in Fig. 2, a), then a low voltage level is formed at the output of the comparator 3, which starts the integral timer 4, a pulse from the output which is amplified by a current amplifier 6, current pulses from which open the electronic switch on the optothyristor 7, and the process is repeated.

If the voltage of the thermocouple 9 from the output of the signal amplifier of the thermocouple 1 is greater than the voltage of the temperature setpoint 2, then a high voltage level is formed at the output of the comparator 3, while the start of the integral timer 4 does not occur.

The experimental model of the temperature controller used LMC6482AIMX operational amplifiers for the thermocouple signal amplifier and comparator, 78L05ABZ positive voltage stabilizer, KR1006VI1 integral timer, T125-12.5 optical thyristor electronic switch, GBU6K - AC bridge rectifier.

Thus, a temperature controller containing a thermocouple signal amplifier, a temperature setting device, a comparator, to the input of which signals from the outputs of the amplifier and temperature setting device are fed, an integral timer controlled by the output signal of the comparator, a positive voltage stabilizer, a current amplifier, an AC bridge rectifier, connected in series an electronic switch on an optothyristor, a heater and a thermocouple, provides an increase in the reliability of the temperature controller and an increase in the accuracy of temperature control of the soldering iron

Claims (1)

A temperature regulator containing a comparator, a temperature regulator, a positive voltage stabilizer, a series-connected heater and a thermocouple, characterized in that the temperature regulator is additionally equipped with a thermocouple signal amplifier, the output of which is connected to the comparator input, an integral timer, the input of which is connected to the comparator output, and its the output is connected to the input of the current amplifier, the output of the current amplifier is connected to an electronic switch on an opto-thyristor, an AC bridge rectifier, to the input of which an AC supply voltage is supplied, and its positive output is connected to an electronic switch on an opto-thyristor, and through a diode to the input of a positive stabilizer voltage and a capacitor connected between the input of the positive voltage regulator and the negative output of the AC bridge rectifier.

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