RU130419U1 - RESISTANCE ELECTRIC FURNACE TEMPERATURE REGULATOR (OPTIONS) - Google Patents

Abstract

1. The temperature regulator of the resistance electric furnace, comprising a temperature adjuster, connected by an output to the summing input of the first comparison element, connected by the output to the summing input of the second comparison element, the output of which is connected through the control device to the input of the voltage regulator connected to the current sensor and resistance electric furnace heaters, equipped with a temperature sensor, connected by an output to a subtracting input of the first comparison element, characterized in that a restriction unit is introduced I, the comparator and the functional unit, connected by the input to the output of the temperature setter, and by the output - to the subtracting input of the comparator connected by the summing input to the output of the current sensor, and the output of the comparator through the restriction unit is connected to the subtracting input of the second comparison element. 2. A temperature regulator of an electric resistance furnace, comprising a temperature regulator, connected by an output to the summing input of the first comparison element, connected by an output to the summing input of a second comparison element, the output of which is connected via an adjusting device to the input of a voltage regulator connected to the output of the current sensor and heaters of the resistance electric furnace equipped with a sensor the temperature associated with the output with the subtracting input of the first comparison element, characterized in that the restriction block is introduced, a comparator and a functional unit connected by an input to the output of the temperature sensor, and by an output to a subtracting input of a comparator connected by a summing input to the output of the current sensor, and the output of the comparator through the limiting unit connect

Description

The proposed solution relates to the field of electrical engineering, in particular to devices for controlling the temperature of an electric resistance furnace.

A known temperature controller of a resistance furnace, comprising a temperature controller, connected by an output to the summing input of the first comparison element, connected by an output to the summing input of the second comparison element, the output of which is connected through the control device to the input of the voltage regulator, the output of which is connected to the current sensor and resistance electric furnace heaters, equipped with a temperature sensor, connected by an output to the subtracting input of the first comparison element, and the output of the current sensor is connected to the subtract ayuschemu input of the second comparison element. (The effect of limiting the current of heaters on the operation of temperature controllers in high-temperature vacuum resistance furnaces / Rubtsov V.P., Mityakov F.E., Goryachikh E.V., Kruchinin A.M. / Vestnik MPEI, 2012, No. 2, p. 82).

In a number of technological processes, a prompt and accurate change in the maximum current value on the heaters is required when the temperature in the furnace changes. This device is not able to fulfill the above requirements, which is its disadvantage.

The technical task is to adapt the parameters of the temperature controller to the changing temperature conditions of the environment and the furnace (boot, heater, thermal insulation), which improves the accuracy of the temperature controller, a more accurate distribution of the temperature regime in the furnace and the speed of the system.

The technical effect is achieved by introducing functional blocks that automatically adapt the value of the current cutoff depending on the temperature.

The problem is solved in that in a known temperature regulator of an electric resistance furnace, comprising a temperature adjuster, connected by an output to a summing input of a first comparison element, connected by an output to a summing input of a second comparison element, the output of which is connected through an adjusting device to the input of a voltage regulator connected to its output by a current sensor and heaters of an electric resistance furnace equipped with a temperature sensor connected to an output with a subtracting input of the first element According to the utility model, a comparator, a limiting unit and a functional unit are introduced, the input of which is connected to the output of the temperature setter, and the output to the subtracting input of the comparator, where the summing input of the comparator is connected to the output of the current sensor, and the output of the comparator through the limiting unit is connected to the subtracting input second element of comparison.

According to the second embodiment, to a known device comprising a temperature adjuster connected to an output with a summing input of a first comparison element connected to an output to a summing input of a second comparison element, the output of which is connected through a control device to the input of a voltage regulator connected to the current sensor and resistance heater heaters by its output equipped with a temperature sensor connected by an output to the subtracting input of the first comparison element, according to a utility model, a comparator to the limitation is a functional block, the input of which is connected to the output of the temperature sensor, and the output to the subtractor input of the comparator, where the summing input of the comparator is connected to the output of the current sensor, and the output of the comparator through the restriction block is connected to the subtracting input of the second comparison element.

In addition, the functional block can be made in the form of an operational amplifier in both versions.

The first option provides correction of the cutoff current at a given temperature, but does not take into account the change in the current temperature in the furnace, which reduces the accuracy of regulation of the controller.

For a number of technological processes in which the resistance of the heater from temperature changes slowly, you can use the first version of the controller. In the case when the resistance of the heater changes constantly, quickly and in large ranges (with a change in temperature), then for such technological processes a second version of the controller should be used.

The device is illustrated by drawings, in which Fig. 1 is a functional diagram of a temperature regulator of an electric resistance furnace related to the first item, and in Fig. 2 - related to the second item.

A device for controlling an electric resistance furnace 1 consists of a voltage regulator 2 connected by an input through a regulating device 3 to the output of the comparison element 4, the summing input of which is connected to the output of the comparison element 5. The resistance electric furnace 1 is equipped with a temperature sensor 7 connected to the subtracting input of the comparison element 5. The summing input of the comparison element 5 is connected to the output of the temperature setter 6, connected through the function block 11 to the subtracting input of the comparator 9, and the summing input to mparatora 9 through the current sensor 8 is connected to the output of the voltage regulator 2. The output of the comparator 9 through the restriction unit 10 is connected to the subtraction input of the comparison element 4. The limiting unit 10 is implemented on standard logic elements and has a characteristic of an input-output U _O = f (U _Rin) presented in figure 3. Functional block 11 is implemented on the basis of an operational amplifier and has the input-output characteristic U _o = φ (θ) shown in Fig. 4, where θ is the temperature in the furnace.

The device operates as follows.

Using the temperature setter 6, a set value of the adjustable temperature Θ _s is formed (manually or automatically). This signal Θ _{s is} supplied to the first comparison element 5, where it is compared with a signal proportional to the temperature Θ measured from the control object 1 (heaters of the electric resistance furnace) by the temperature sensor 7. Regulating device 3 depending on the value ΔΘ = Θ _s- Θ and its sign deviation forms a regulatory effect on the actuator (voltage regulator 2), which directly affects the control object 1. The controller provides current feedback. The signal from the current sensor 8 is fed through the restriction unit 10 to the second comparison element 4. Due to this feedback, a smoother output mode of the control object 1 to a predetermined temperature is provided.

Compared with the prototype, the proposed device provides automatic adaptation of the current cutoff value depending on the required temperature for various technological processes. This is achieved by introducing a functional unit 11, a comparator 9 and a restriction unit 10. The signal from the temperature setter 6 is fed to the input of the functional unit 11, which generates a given signal and supplies it to the input of the comparator 9, providing correction of current and cutoff depending on temperature.

According to the second variant, the device for controlling the resistance electric furnace 1 consists of a voltage regulator 2 connected by an input through a regulating device 3 to the output of the comparison element 4, the summing input of which is connected to the output of the comparison element 5. The resistance electric furnace 1 is equipped with a temperature sensor 7 connected to the subtracting input of the element comparison 5 and the input of the function block 11. The summing input of the comparison element 5 is connected to the output of the temperature setter 6. Function block 11 is connected to the subtracting input to the comparator 9, and the summing input of the comparator 9 through the current sensor 8 is connected to the output of the voltage regulator 2. The output of the comparator 9 through the restriction block 10 is connected to the subtracting input of the comparison element 4. The restriction block 10 is implemented on standard logic elements and has an input-output characteristic U _o = f (U _o ) presented in figure 3. Functional block 11 is implemented on the basis of an operational amplifier and has the input-output characteristic U _o = φ (θ) shown in Fig. 4, where θ is the temperature in the furnace.

The device operates as follows.

Using the temperature setter 6, a set value of the adjustable temperature Θ _s is formed (manually or automatically). This signal Θ _{s is} supplied to the first comparison element 5, where it is compared with a signal proportional to the temperature Θ measured from the control object 1 (heaters of the electric resistance furnace) by the temperature sensor 7. Regulating device 3 depending on the value ΔΘ = Θ _s- Θ and its sign deviation forms a regulatory effect on the actuator (voltage regulator 2), which directly affects the control object 1. The controller provides current feedback. The signal from the current sensor 8 is fed through the restriction unit 10 to the second comparison element 4. Due to this feedback, a smoother output mode of the control object 1 to a predetermined temperature is provided.

Compared with the prototype, the proposed device provides automatic adaptation of the current cutoff value depending on the required temperature for various technological processes. This is achieved by introducing a functional unit 11, a comparator 9 and a restriction unit 10. The signal from the temperature sensor 7 is fed to the input of the functional unit 11, which generates a given signal and feeds it to the input of the comparator 9, providing correction of current and cutoff depending on temperature.

Claims (4)

1. The temperature regulator of the resistance electric furnace, comprising a temperature adjuster, connected by an output to the summing input of the first comparison element, connected by the output to the summing input of the second comparison element, the output of which is connected through the control device to the input of the voltage regulator connected to the current sensor and resistance electric furnace heaters, equipped with a temperature sensor, connected by an output to a subtracting input of the first comparison element, characterized in that a restriction unit is introduced I, the comparator and the functional block, connected by the input to the output of the temperature setter, and by the output - to the subtracting input of the comparator connected by the summing input to the output of the current sensor, and the output of the comparator through the restriction unit is connected to the subtracting input of the second comparison element. 2. The temperature regulator of the resistance electric furnace, comprising a temperature adjuster, connected by an output to the summing input of the first comparison element, connected by the output to the summing input of the second comparison element, the output of which through the control device is connected to the input of the voltage regulator, connected by the output to the current sensor and resistance electric heaters, equipped with a temperature sensor, connected by an output to a subtracting input of the first comparison element, characterized in that a restriction unit is introduced I, the comparator and the functional unit, connected by the input to the output of the temperature sensor, and by the output to the subtracting input of the comparator connected by the summing input to the output of the current sensor, and the output of the comparator through the restriction unit is connected to the subtracting input of the second comparison element. 3. The temperature controller of the resistance electric furnace according to claim 1, characterized in that the functional unit is made in the form of an operational amplifier. 4. The temperature controller of the resistance electric furnace according to claim 2, characterized in that the functional unit is made in the form of an operational amplifier.

Images