KR100933372B1 - Power fuse disconnection device in case of control rectifier failure of warmer - Google Patents

Abstract

The present invention continuously monitors the operating state of control rectifiers such as SCR, TRIAC, etc. used in heaters such as electric blankets, electric yokes, electric steamers, etc., and when the heat does not operate normally due to an abnormality, the heating wire heater is continuously disconnected. The present invention relates to a power fuse disconnection device when a control rectifier element of a heater does not generate heat, and checks whether a gate trigger voltage for turning on the control rectifier device is supplied to the gate stage, and in response to the supply of the gate trigger voltage. If the heating wire heater generates heat even when the gate trigger voltage is not supplied by checking whether the heater is being heated, the heating wire heater operates regardless of the temperature control signal when the power control control rectifier used in the heater fails. That a fire It is effective to prevent it in advance.

Heater, electric blanket, electric cooler, electric steamer, control rectifier, fault diagnosis, power fuse, disconnection, comparative amplifier, op amp, microcomputer

Description

Power fuse disconnection device in case of control rectifier failure of warmer

The present invention relates to a power supply fuse disconnection device in the case of a control rectifier element of a heater.

More specifically, it continuously monitors the operation status of control rectifiers such as SCR and TRIAC used in heaters such as electric blankets, electric yokes, and electric steamers, and when the abnormal operation does not work, the power fuse is disconnected and the heating wire heater The present invention relates to a power fuse disconnection device in case of failure of a control rectifier of a heater that prevents continuous heat generation.

In general, in order to maintain the temperature of the bed properly, electric bedding, electric bedding, and electric steamers such as electric heaters are used a lot. In order to control the temperature of the heating wire in the electrothermal bedding and the heater, a control rectifier SCR or TRIAC is used as a control element for supplying power to the heating wire.

Therefore, when the control rectifier used as a control element loses its control function for other reasons, the heating wire heater continues to generate heat, causing a burn or fire accident.

The present invention has been made to solve the above problems, by continuously monitoring the operating state of the control rectifier element such as SCR, TRIAC, etc. used in warmers such as electric blanket, electric yoke, electric steamer, normal operation due to abnormal occurrence It is an object of the present invention to provide a power fuse disconnection device in the case of a failure of the control rectifier element of the electric heating bed that causes the heating wire heater not to continuously generate heat by disconnecting the power fuse.

That is, when the control input gate signal voltage of the control rectifier SCR or TRIAC and the anode voltage or the heating voltage are compared with the MICOM chip or the comparative amplifier, if the heating voltage is detected without the gate signal voltage, the heating line control rectifier is It is determined that the SCR or TRIAC device has lost control, and the power supply fuse is disconnected to prevent the heating wire from continuously generating heat.

The configuration of the present invention for achieving the above object is, the power supply fuse disconnection device when the control rectifier element of the electrothermal bed failure, heating wire heater; A power source and a temperature controller configured to generate and output a gate trigger voltage in response to a heating temperature set by a user; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage to generate heat; A gate trigger voltage detector detecting a gate trigger voltage supplied to the heating line heater driver; An exothermic voltage detector configured to detect and convert an exothermic current supplied to the exothermic wire heater into an exothermic voltage; A power supply fuse disconnection controller for comparing the gate trigger voltage input from the gate trigger voltage detector with the heating voltage input from the heating voltage detector, and outputting a power supply disconnection signal according to the comparison result; And a power fuse disconnection unit for disconnecting the power fuse in response to the power fuse disconnection signal.

The gate trigger voltage detector includes a rectifier device for detecting the gate trigger voltage, a charging device charged by the gate trigger voltage, and a delay device for smoothing and delaying a signal voltage supplied from the charging device. The exothermic voltage detector comprises a rectifying element for detecting the exothermic voltage, a charging element charged with the exothermic voltage, and a delay element for smoothing and delaying a signal voltage supplied from the charging element.

The power fuse disconnection controller may include a first switching device turned on or off by a signal voltage output from the gate trigger voltage detector, and a second switch turned on or off by a signal voltage of the first switching device or the heating voltage detector. Characterized in that it comprises a switching element.

The power fuse disconnection control unit receives a signal voltage output from the gate trigger voltage detection unit through a non-inverting terminal (-), receives a signal voltage output from the heating voltage detection unit as an inverting terminal (+), and compares two signals. And a comparator for outputting a power fuse disconnection signal according to the comparison result.

The power fuse disconnection unit may include: a resistor configured to receive a power fuse disconnection signal input from the power fuse disconnection controller; a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal; And a heat generating resistor connected to the anode end of the rectifying device to generate heat according to the driving of the control rectifying device, and generating the heat generating resistor to disconnect the power fuse.

The power fuse disconnection unit may include: a resistor configured to receive a power fuse disconnection signal input from the power fuse disconnection controller; a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal; And a resistance element connected to the anode end of the rectifying element, the current capacitance value of which is changed according to the driving of the control rectification element, wherein the power supply fuse is disconnected by exceeding the current capacitance value of the resistance element.

The power fuse disconnection unit includes a resistance element receiving a power fuse disconnection signal input from the power fuse disconnection control unit, and a control rectification device driven by a power fuse disconnection signal applied from the resistance element connected to the gate terminal. The power supply fuse may be disconnected by supplying an overcurrent to the control rectifier.

An apparatus for disconnecting power supply when a control rectifier element of an electric heating bed fails, comprising: a heating wire heater; A power supply and a temperature controller for outputting a temperature control signal according to a user's operation; A microcomputer outputting a gate trigger voltage in response to the temperature control signal and outputting a power fuse disconnection signal when a heating voltage is input from an external state when the gate trigger voltage is not output; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage of the microcomputer to generate heat; A heating voltage detector detecting the heating voltage applied to the heating line heater and outputting the heating voltage to the microcomputer; And a power fuse disconnection unit for disconnecting the power fuse in response to the power fuse disconnection signal of the microcomputer.

The heating wire heater driving unit includes a resistor device receiving a gate trigger voltage from the microcomputer, a rectifier device connected to the resistor device by direct current, and a control rectifier device driven by receiving a gate trigger voltage from the rectifier device connected to a gate terminal. The heating voltage detector may include a resistor connected to the cathode terminal of the control rectifier in series to output the heating voltage to the microcomputer.

The heating voltage detecting unit is connected between an anode terminal of the control rectifying device and the microcomputer, and includes a resistor device that detects the heating voltage supplied to the anode terminal and outputs the heating voltage to the microcomputer.

The power fuse disconnection unit may include a resistor configured to receive a power fuse disconnection signal input from the microcomputer, a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal, and an anode of the control rectifier device. And a heat generating resistor element connected to the stage and generating heat according to the driving of the control rectifier element, and generating the heat generating resistor element to disconnect the power fuse.

The power fuse disconnection unit may include a resistor configured to receive a power fuse disconnection signal input from the microcomputer, a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal, and an anode of the control rectifier device. And a resistance element connected to a stage, the current capacitance value of which is changed according to the driving of the control rectification element, and characterized in that the power fuse is disconnected by exceeding the current capacitance value of the resistance element.

The power fuse disconnection unit includes a resistance element receiving a power fuse disconnection signal input from the microcomputer, and a control rectifier device driven by a power fuse disconnection signal applied from the resistance element connected to a gate terminal. An overcurrent is supplied to the power supply to disconnect the power fuse.

An apparatus for disconnecting power supply when a control rectifier element of an electric heating bed fails, comprising: a heating wire heater; A power source and a temperature controller configured to generate and output a gate trigger voltage in response to a heating temperature set by a user; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage to generate heat; A gate trigger voltage detector detecting a gate trigger voltage supplied to the heating line heater driver; An exothermic voltage detector configured to detect and convert an exothermic current supplied to the exothermic wire heater into an exothermic voltage; And a power fuse disconnection unit comparing the gate trigger voltage input from the gate trigger voltage detection unit with the heating voltage input from the heating voltage detection unit, and disconnecting the power supply fuse according to the comparison result.

The gate trigger voltage detector includes a rectifier device for detecting the gate trigger voltage, a charging device charged by the gate trigger voltage, and a delay device for smoothing and delaying a signal voltage supplied from the charging device. The exothermic voltage detector comprises a rectifying element for detecting the exothermic voltage, a charging element charged by the exothermic voltage, and a delay element for smoothing and delaying a signal voltage supplied from the charging element.

The power fuse disconnection unit may include a power supply fuse, a heat generating resistor device for disconnecting the power fuse, a first switching device turned on or off by a signal voltage output from the gate trigger voltage detector, the first switching device or the And a second switching device turned on or off by the signal voltage of the heating voltage detector, and when the signal voltage is output from the heating voltage detector while the signal voltage is not output from the gate tree voltage detector. It is turned on so that a current flows through the heat generating element.

The power fuse disconnection unit may include a power supply fuse, a heating resistor device for disconnecting the power fuse, a switching device turned on or off by a signal voltage output from the gate trigger voltage detector, the switching device or the heating voltage detection unit. And a control rectifying element which is turned on or off by a signal voltage, and when the control voltage is turned on by outputting a signal voltage from the heating voltage detector in a state in which the signal voltage is not output from the gate tree voltage detector. It is characterized by generating heat by allowing a current to flow.

The present invention monitors the control capability of the control rectifier SCR or TRIAC applied as a control element for heating the heater in a simplified configuration, and when the control ability is lost, the power fuse is disconnected by controlling the power fuse disconnection circuit to continuously generate heat. By blocking the temperature and rise that can occur, there is an effect to prevent the fire in advance.

Hereinafter, the configuration of the present invention will be described in detail with reference to embodiments of the present invention illustrated in the accompanying drawings.

(Example using an analog transistor)

1 is a view showing the configuration of a power supply fuse disconnection device when a control rectifier element of an electrothermal bed employing an analog transistor according to the present invention.

As shown in FIG. 1, when the control rectifier element of the electrothermal bedding employing an analog transistor fails, the power fuse disconnection device includes a heating wire heater 7 and a power source for generating and outputting a gate trigger voltage in response to a heating temperature set by a user; A temperature control unit 60, a heating wire heater driver 70 for supplying a heating current to the heating wire heater 7 in response to the gate trigger voltage to generate heat, and a gate trigger voltage supplied to the heating wire heater driving unit 70. Is input from the gate trigger voltage detection unit 20 for detecting the voltage, the heating voltage detection unit 30 for converting the heating current supplied to the heating line heater 7 into the heating voltage, and detecting the heating voltage. The gate trigger voltage is compared with the heating voltage input from the heating voltage detection unit 30, and power supply fuse is disconnected according to the comparison result. Outputting a power consists of fuse disconnection control section 40, and a power fuse part 50 to break the power fuse in response to the power fuse signal.

The gate trigger voltage detector 20 includes a diode 12 receiving the gate trigger voltage from the power supply and temperature controller 60, a capacitor 13 charged by a heating voltage applied through the diode 12, and And a resistor 14 for smoothing the exothermic voltage signal applied from the capacitor 13.

The heating voltage detection unit 30 includes a diode 15 that receives the heating voltage from the heating line driver 70, a capacitor 16 and the capacitor 16 charged by the heating voltage applied through the diode 15. And a resistor 17 for smoothing the exothermic voltage signal applied from the same.

The power fuse disconnection control unit 40 includes a transistor 11 having a resistor 17 connected to a base terminal and outputting a heating voltage to an anode terminal, and a resistor 14 connected to the base terminal. The transistor 10 is configured to output a gate trigger voltage.

As shown in FIG. 1, the power fuse disconnection unit 50 includes a resistor element 3 receiving a power fuse disconnection signal input from the power fuse disconnection control unit 40 and the resistor element 3 connected to a gate end. A control rectifying element 2 driven by a power fuse disconnection signal applied from the power source; and a heat generating resistor element connected to an anode end of the control rectifying element 2 and generating heat according to the driving of the control rectifying element 2; 1) (or a heat generating resistor), and heats the heat generating resistor 1 to disconnect the power fuse.

In addition, the power fuse disconnection unit 50 includes a resistor 3 for receiving a power fuse disconnection signal input from the power fuse disconnection control unit 40 as shown in FIG. 12, and the resistor connected to the gate terminal. (3) is connected to the control rectification element (2) driven by the power fuse disconnection signal applied from the (3) and the anode of the control rectification element (2), the current capacitance value according to the drive of the control rectification element (2) A variable resistance element 31 is provided, and the power supply fuse is disconnected by exceeding the value of the current capacity of the resistance element 31.

In addition, as shown in FIG. 13, the power fuse disconnection unit 50 includes a resistor 3 for receiving a power fuse disconnection signal input from the power fuse disconnection controller 40 and the resistor connected to a gate terminal. And a control rectifier element 2 driven by the power fuse disconnection signal applied from (3), and overcurrent is supplied to the control rectifier element 2 to disconnect the power fuse.

Referring to the operation of the power supply fuse disconnection device when the control rectifier element of the electrothermal bed employing the analog transistor configured as described above is as follows.

First, the case in which the gate trigger voltage is output from the power and temperature controller 60 according to the user's operation will be described. As shown in FIG. 1, the gate trigger voltage output from the power and temperature controller 60 is When the resistor 4 is applied to the diode 5 and is applied to the gate terminal of the control rectifier 6 by the diode 5, the control rectifier 6 is the AC power supplied through the power supply fuse heating heater The heating-wire heater 7 generates heat by being turned on to be supplied to (7).

In this case, the gate trigger voltage output from the power supply and temperature controller 60 is applied to the diode 12 of the gate trigger voltage detector 20, and the gate trigger voltage output through the diode 12 is the condenser 13. The charging voltage is smoothed by the resistor 14 and applied to the base terminal of the transistor 10 of the power fuse disconnection controller 40. As a result, the transistor 10 is turned on. Therefore, since the base terminal of the transistor 11 is applied with zero voltage and the low level signal is input to the base terminal of the transistor 11, the transistor 11 performs the turn-off operation.

Therefore, since the current does not flow to the resistor 3 of the power fuse disconnection unit 50 and a low level signal is applied to the gate terminal of the control rectifier 2, the control rectifier 2 is turned off. . In this way, the power supply fuse does not disconnect and supplies power to the entire circuit to perform normal operation.

Next, when the control rectifying element 6 does not operate normally when the heating line heater 7 is generating heat, that is, when the gate trigger voltage is not output from the power supply and temperature controller 60, the control rectifying element ( When 6) is kept in the on state, no voltage is applied to the diode 12 of the gate trigger voltage detection unit 20, and thus no voltage is applied to the capacitor 13 and the resistor 14. Accordingly, a low level signal is also applied to the base terminal of the transistor 10 of the power fuse disconnection controller 40 to be turned off.

Therefore, the exothermic voltage supplied from the exothermic voltage detection unit 30 is applied to the base terminal of the transistor 11 of the power supply fuse disconnection control unit 40, and the transistor 11 is turned on. Accordingly, a heat generation voltage is output through the emitter terminal of the transistor 11, and the heat generation voltage is supplied to the resistor 3 of the power fuse disconnection unit 50 through the resistor 18 as a power fuse disconnection signal.

Then, the rectifier control element 2 of the power fuse disconnection unit 50 is turned on by the power fuse disconnection signal supplied through the gate terminal, and the heat generating resistor 1 is heated by a current flowing in the heat generating resistor 1. When the heat generating temperature of the heat generating resistor 1 rises above a predetermined temperature, the power fuse is disconnected to cut off power supply.

On the other hand, in the method of disconnecting the power supply fuse, instead of the heating resistor 1, a resistor 31, which can change the value of the current capacitance as shown in FIGS. 12 and 13, is used to exceed the value of the current capacitance. The power supply fuse may be disconnected or an overcurrent may be supplied to the control rectifier 2 to disconnect the power supply fuse.

The above contents are summarized as follows.

Condition Heating signal voltage condition Resistance (18) output Gate signal voltage HI X LO LO HI HI LO LO LO

'X' in the table means that there is no heating signal voltage.

(Example using an OPAmp)

As shown in FIG. 2, the op amp employs two transistors 10 and 11 with respect to the power supply fuse disconnection controller 40 including two transistors 10 and 11 shown in FIG. 1. As an alternative to the OP Amp, the operation is the same as in the embodiment employing the analog transistor, and thus the detailed description thereof will be omitted. That is, the op amp of the power fuse disconnection controller 40 receives the trigger gate voltage output from the gate trigger voltage detector 20 through an inverting terminal (-), and the heating voltage detector (+) through a non-inverting terminal (+). The heating voltage output from 30 is received.

Therefore, when the gate trigger voltage is input to the inverting terminal (-) and the heating voltage is input to the non-inverting terminal (+), a low level voltage signal is output to the output terminal. The low-level voltage signal is applied to the gate terminal of the control rectifying element 2 of the power supply fuse disconnection unit 50 and turned off, and the entire circuit is normally driven.

On the other hand, when a heating voltage is applied to the non-inverting terminal (+) while the gate trigger voltage is not input to the inverting terminal (-), (+) power is output to the output terminal of the OP amp, and the (+ The power is input to the gate terminal of the control rectifier 2 through the resistor 3 of the power fuse disconnection unit 50 as a power fuse disconnection signal, and the control rectifier 2 is turned on by the power fuse disconnection signal. do. Accordingly, the heat generating resistor 1 starts to generate heat, and when the heat generating temperature rises above a predetermined temperature, the power supply fuse is disconnected and the driving power supplied to the entire circuit is cut off, thereby preventing the entire circuit from operating.

(Example that adopted a microcomputer)

The power fuse disconnection device when the control rectifier element of the electrothermal bedding employing a microcomputer is broken, as shown in FIG. 3, a heating wire heater 7 and a power supply and a temperature control unit 60 outputting a temperature control signal according to a user's operation And a microcomputer 80 outputting a gate trigger voltage in response to the temperature control signal, and outputting a power fuse disconnection signal when a heating voltage is input from a heating line heater driver 70 to be described later in a state in which the gate trigger voltage is not output. ), A heating wire heater driver 70 for supplying a heating current to the heating wire heater 7 to generate heat in response to the gate trigger voltage of the microcomputer 80, and a heating voltage applied to the heating wire heater 7. Heat generation voltage detection unit 90 outputting to the microcomputer 80 and power fuse disconnection unit 50 for disconnecting the power fuse in response to the power fuse disconnection signal of the microcomputer 80. It is composed of

The exothermic voltage detector 90 includes a resistor 8.

As shown in FIG. 3, the power fuse disconnection unit 50 is applied from the resistor 3 receiving the power fuse disconnection signal input from the microcomputer 80 and the resistor 3 connected to the gate terminal. A control rectifier element 2 driven by a power supply disconnection signal, and a heat generating resistor element 1 connected to an anode end of the control rectifier element 2 and generating heat according to the driving of the control rectifier element 2; And heats the heat generating resistor 1 to disconnect the power fuse.

In addition, as shown in FIG. 12, the power fuse disconnection unit 50 includes a resistor element 3 receiving a power fuse disconnection signal input from the microcomputer 80, and the resistor element 3 connected to a gate end. The control rectification element 2 driven by the power supply disconnection signal applied from the resistor and the resistance element connected to the anode terminal of the control rectification element 2 and whose current capacitance value changes according to the driving of the control rectification element 2. (31), and the power supply fuse is disconnected by exceeding the value of the current capacity of the resistance element (31).

In addition, as shown in FIG. 13, the power fuse disconnection unit 50 includes a resistor 3 for receiving a power fuse disconnection signal input from the microcomputer 80, and the resistor 3 connected to a gate terminal. And a control rectifying element (2) driven by a power fuse disconnection signal applied from the circuit. The overcurrent is supplied to the control rectifying element (2) to disconnect the power supply fuse.

Referring to the operation of the power fuse disconnection device when the control rectifier element failure of the heat transfer bed employing the microcomputer configured as described above are as follows.

First, when the user applies power through the power and temperature controller 60 and sets an appropriate temperature, the microcomputer 80 gate trigger voltage to operate the heater at the temperature set by the power and temperature controller 60. Is output to the heating wire heater driver 70. That is, as shown in FIG. 6, when the gate trigger voltage (ON signal) for driving the control rectifier 6 is input from the microcomputer 80 to the control rectifying element 6 while the AC power is supplied, the AC power is supplied. The heating wire heater 7 is supplied to the heating wire heater 7 to generate heat.

Then, when the heating line heater driver 70 receives the gate trigger voltage through the resistor 4 and outputs the gate trigger voltage to the gate terminal of the control rectifier 6 through the diode 5, the control rectifier 6 is turned on. At this time, the microcomputer 80 outputs a low level voltage to the power fuse disconnection unit 50 so that the control rectification element 2 of the power supply fuse disconnection unit 50 is turned off. 4 and 5 are equivalent circuit diagrams of the normal operation, the microcomputer 80 continuously checks the output state of the heating voltage through the heating voltage detector 90 formed of the resistor 8. That is, as shown in FIGS. 6 and 7, the microcomputer 80 receives the voltage E2 applied to the resistor 8 of the heating voltage detector 90 to determine whether the control rectifier 2 is normally present.

On the other hand, when the microcomputer 80 detects the heating voltage output state through the heating voltage detector 90 while the gate trigger voltage is not output to the heating line heater driving 70, the microcomputer 80 detects the heating voltage. A high level power fuse disconnection signal is output to the resistor 3 of the power fuse disconnection unit 50, the rectifier control element 2 is turned on in response to the power fuse disconnection signal, and the heating resistor element 1 starts to generate heat. In addition, the heat generating temperature of the heat generating resistor 1 is raised above a predetermined temperature so that the power fuse is disconnected.

As another embodiment of the power fuse disconnection device when the control rectifier element of the electric heating bed employing the microcomputer is adopted, as shown in FIG. 8, the microcomputer 80 controls the heating voltage of the heating wire heater 7 by the heating line heater driver 40. It is to be detected through the resistor 9 connected to the anodizing side of the rectifying element 6, the exothermic voltage applied to the resistor 8 of the exothermic voltage detecting unit 90 of FIG. The exothermic voltages across the phases are opposite to each other. 9 and 10 are equivalent circuit diagrams in which the control rectifying element 6 operates normally. As shown in FIG. 11, the gate trigger voltage ON of the high level is applied to the gate terminal of the control rectifying element 6. When input, the zero voltage is input to the exothermic voltage E1 shown in FIG. 11 through the resistor 9. That is, if the microcomputer 80 has a voltage E1 applied to the resistor 9 when the low signal is applied to the gate terminal of the control rectifying element 6 and is in the off state, the control rectifying element 6 operates normally and the resistance ( If the voltage E1 applied to 9) does not exist, it is determined that the control rectifying element 6 is not operating normally, and the power supply fuse is disconnected.

(Integrated Power Fuse Disconnection  Adopted Example )

As shown in FIGS. 14 and 15, when the control rectifier element of the electric heating bed adopts the power fuse disconnection unit in which the power fuse disconnection control unit is integrally formed, the power fuse disconnection device includes a heating wire heater 7 and heat generated by the user. A power supply and temperature controller 60 generating and outputting a gate trigger voltage in response to a temperature, a heating wire heater driver 70 for supplying a heating current to the heating wire heater in response to the gate trigger voltage, and generating heat; A gate trigger voltage detection unit 20 for detecting a gate trigger voltage supplied to the driver 70, a heating voltage detection unit 30 for converting and detecting a heating current supplied to the heating line heater into a heating voltage, and the gate trigger voltage The gate trigger voltage input from the detector 20 is compared with the heating voltage input from the heating voltage detector 30. And the power supply fuse disconnection unit 42 for disconnecting the power supply fuse according to the comparison result.

The gate trigger voltage detection unit 20 smoothes and delays the rectifying element 12 that detects the gate trigger voltage, the charging element 13 charged by the gate trigger voltage, and a signal voltage supplied from the charging element. It consists of a delay element 14, the heating voltage detection unit 30 is a rectifying device 15 for detecting the heating voltage, the charging device 16 is charged by the heating voltage, and the charging device 16 It consists of a delay element 17 to smooth and delay the signal voltage supplied from the ().

As illustrated in FIG. 14, the power fuse disconnection unit 42 is turned on by a power supply fuse, a heat generating resistor 1 for disconnecting the power fuse, and a signal voltage output from the gate trigger voltage detector 20. Or a first switching element 10 that is turned off and a second switching element 11 that is turned on or off by a signal voltage of the first switching element 10 or the heating voltage detection unit 30. When the signal voltage is output from the heating voltage detection unit 30 while the signal voltage is not output from the tree voltage detection unit 20, the second switching element 11 is turned on so that a current flows in the heating resistance element 1. Heat it up.

The power fuse disconnection part 42 is changeable as shown in FIG. 15. That is, the power supply fuse disconnection unit 45 of FIG. 15 is switched on or off by the power supply fuse, the heat generating resistor 1 for disconnecting the power supply fuse, and the signal voltage output from the gate trigger voltage detector 20. An element 10 and a control rectifying element 11A that is turned on or off by the signal voltage of the switching element 10 or the heating voltage detection unit 30, and the signal voltage in the gate tree voltage detection unit 20. When the signal voltage is output from the heating voltage detection unit 30 in the non-output state, when the control rectifying element 11A is turned on, a current flows to the heating resistance element 1 to generate heat.

Referring to the operation of the power fuse disconnection device when the control rectifier element failure of the heat transfer bed configured as described above is as follows.

Referring to the power fuse disconnection unit 42 illustrated in FIG. 14, when the heating voltage is detected by the heating voltage detector 30 when the gate trigger voltage is normally output, the embodiment described with reference to FIG. Since the same, detailed description thereof will be omitted here.

When the heating voltage is detected by the heating voltage detector 30 at the time when the gate trigger voltage is not output from the power supply and the temperature controller 60, the first switching of the power fuse disconnection unit 42 is performed. Since the low level signal voltage is applied to the base end of the element 10, the first switching element 10 is turned off, and the base end of the second switching element 11 is provided from the heating voltage detector 30. Since the high level signal voltage is applied, the second switching element 11 is turned on. Therefore, the power supplied by the power source AC is applied not only to the heating line heater 7 but also to the heating resistance element 1, so that the heating resistance element 1 starts to generate heat. The power supply fuse is disconnected when the heat generating temperature of the heat generating resistor 1 rises above a predetermined temperature.

Finally, a description will be given of the power fuse disconnection unit 42 shown in FIG. 15. When the heating voltage is detected by the heating voltage detection unit 30 when the gate trigger voltage is normally output, 10) is turned on. In addition, a high level signal voltage of the heating voltage detection unit 30 is applied to the gate terminal of the control rectifying element 11A, but before that, the switching element 10 first lowers the gate terminal of the control rectifying element 11A. Since the signal voltage of the level is applied, the control rectifying element 11A maintains the turn-off state and the power supply fuse is normally maintained.

At this time, when the heating voltage is detected by the heating voltage detector 30 when the gate trigger voltage is not output from the power and temperature controller 60, the base end of the switching element 10 of the power fuse disconnection unit 45 is detected. Since the low level signal voltage is applied, the switching element 10 is turned off, and the high level signal voltage is applied from the heating voltage detection unit 30 to the gate terminal of the control rectifying element 11A. The ruler 11A is turned on. Therefore, the power supplied by the power source AC is applied not only to the heating line heater 7 but also to the heating resistance element 1, so that the heating resistance element 1 starts to generate heat. The power supply fuse is disconnected when the heat generating temperature of the heat generating resistor 1 rises above a predetermined temperature.

The control rectifying element mentioned in the present invention includes a thyristor (SCR) or triac (TRIAC) and the like. In addition, reference numeral 42 of FIG. 14 and reference numeral 45 of FIG. 15 denote reference numerals in dotted lines connecting interconnected dotted block boxes in a state in which two dotted block boxes are integrally formed.

1 is a view showing the configuration of a power supply fuse disconnection device when a control rectifier element of a heater employing an analog transistor according to the present invention fails.

FIG. 2 is a diagram illustrating a configuration of a power fuse disconnection device when a control rectifier element of a heater employing an analog OPAmp according to the present invention fails.

3 is a view showing the configuration of the power supply fuse disconnection device when the control rectifier element of the heater employing the microcomputer according to the present invention.

4 and 5 and 9 and 10 is an equivalent circuit diagram of the power supply fuse disconnection device when the control rectifier element of the heater fails when the control rectifier element fails.

6 and 7 and 11 is a waveform diagram of the basic operation signal of the power supply fuse disconnection device when the control rectifier element of the heater according to the present invention fails.

12 and 13 are embodiments of the power fuse disconnection unit of FIGS. 1 to 3, and FIGS. 14 and 15 are circuit diagrams for describing an operation.

<Description of Symbols for Main Parts of Drawings>

1, 3, 4, 8, 14, 17, 18: Resistance (element)

2, 6: Control rectifier (SCR)

5, 12, 15: rectifier diode

10, 11: transistor

13, 16: condenser

Claims (17)

In the fuse breaker of the power supply when the control rectifier element of the heater is broken, Heating wire heater; A power source and a temperature controller configured to generate and output a gate trigger voltage in response to a heating temperature set by a user; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage to generate heat; A gate trigger voltage detector detecting a gate trigger voltage supplied to the heating line heater driver; An exothermic voltage detector configured to detect and convert an exothermic current supplied to the exothermic wire heater into an exothermic voltage; A power supply fuse disconnection controller for comparing the gate trigger voltage input from the gate trigger voltage detector with the heating voltage input from the heating voltage detector, and outputting a power supply disconnection signal according to the comparison result; And A power fuse disconnection unit for disconnecting the power fuse in response to the power fuse disconnection signal; Power supply fuse disconnection device when a fault occurs in the control rectifier of the heater. The method of claim 1, The gate trigger voltage detector, A rectifier device for detecting the gate trigger voltage, a charging device charged by the gate trigger voltage, and a delay device for smoothing and delaying a signal voltage supplied from the charging device, The heating voltage detection unit, A rectifier for detecting the heating voltage, a charging device charged by the heating voltage, and a delaying device for smoothing and delaying the signal voltage supplied from the charging device. Fuse breaker. The method of claim 1, The power fuse disconnection control unit, A first switching element turned on or off by a signal voltage output from the gate trigger voltage detector; And a second switching element which is turned on or off by the signal voltage of the first switching element or the heating voltage detection unit. The method of claim 1, The power fuse disconnection control unit, The signal voltage output from the gate trigger voltage detector is input to the inverting terminal (-), the signal voltage output from the heating voltage detector is input to the non-inverting terminal (+), and the two signals are compared. Power supply fuse disconnection device in case of failure of the control rectifier of the heater, characterized in that the comparator for outputting a fuse disconnection signal. The method of claim 1, The power fuse disconnection unit may include: a resistor configured to receive a power fuse disconnection signal input from the power fuse disconnection controller; a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal; And a heat generating resistor connected to the anode end of the rectifying device to generate heat according to the driving of the control rectifying device, wherein the heat generating fuse generates heat to disconnect the power fuse. Disconnection device. The method of claim 1, The power fuse disconnection unit may include: a resistor configured to receive a power fuse disconnection signal input from the power fuse disconnection controller; a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal; A control element connected to the anode end of the rectifier element is provided with a resistance element that changes the current capacitance value in accordance with the operation of the control rectifier element, the control station of the heater, characterized in that for breaking the power supply fuse by exceeding the current capacity value of the resistance element Power fuse disconnection device in case of failure. The method of claim 1, The power fuse disconnection unit includes a resistance element receiving a power fuse disconnection signal input from the power fuse disconnection control unit, and a control rectification device driven by a power fuse disconnection signal applied from the resistance element connected to the gate terminal. The power supply fuse disconnection device of the failure of the control rectifier device of the heater, characterized in that the power supply fuse is disconnected by supplying an overcurrent to the control rectifier device. In the fuse breaker of the power supply when the control rectifier element of the heater is broken, Heating wire heater; A power supply and a temperature controller for outputting a temperature control signal according to a user's operation; A microcomputer outputting a gate trigger voltage in response to the temperature control signal and outputting a power fuse disconnection signal when a heating voltage is input from an external state when the gate trigger voltage is not output; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage of the microcomputer to generate heat; A heating voltage detector detecting the heating voltage applied to the heating line heater and outputting the heating voltage to the microcomputer; And A power fuse disconnection unit to disconnect the power fuse in response to the power fuse disconnection signal of the microcomputer; Power supply fuse disconnection device when a fault occurs in the control rectifier of the heater. The method of claim 8, The heating wire heater driving unit includes a resistor device receiving a gate trigger voltage from the microcomputer, a rectifier device connected to the resistor device by direct current, and a control rectifier device driven by receiving a gate trigger voltage from the rectifier device connected to a gate terminal. , And the heating voltage detection unit is connected to a cathode terminal of the control rectifying device in series and includes a resistor device for outputting the heating voltage to the microcomputer. The method of claim 8, The heating voltage detecting unit is connected between an anode terminal of the control rectifying element and the microcomputer, and a faulty control rectifier of the heater, characterized in that the resistance element for detecting the heating voltage supplied to the anode and outputting to the microcomputer. Power fuse disconnection device. The method of claim 8, The power fuse disconnection unit may include a resistor configured to receive a power fuse disconnection signal input from the microcomputer, a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal, and an anode of the control rectifier device. It is connected to the stage is provided with a heat generating resistance element that generates heat in accordance with the drive of the control rectification element, The power supply fuse disconnection device of a failure of the control rectifier element of the heater, characterized in that the heat generating resistor element to generate heat to disconnect the power fuse. The method of claim 8, The power fuse disconnection unit may include a resistor configured to receive a power fuse disconnection signal input from the microcomputer, a control rectifier device driven by a power fuse disconnection signal applied from the resistor connected to a gate terminal, and an anode of the control rectifier device. It is connected to the stage and provided with a resistance element that changes the current capacity value in accordance with the drive of the control rectifier, The power supply fuse disconnection device of the failure of the control rectifier element of the heater, characterized in that for breaking the power supply fuse by exceeding the current capacity value of the resistance element. The method of claim 8, The power fuse disconnection unit includes a resistance element receiving a power fuse disconnection signal input from the microcomputer, and a control rectifier device driven by a power fuse disconnection signal applied from the resistance element connected to a gate terminal. The power supply fuse disconnection device of the failure of the control rectifier device of the heater, characterized in that the power supply fuse is disconnected by supplying an overcurrent to the control rectifier device. In the fuse breaker of the power supply when the control rectifier element of the heater is broken, Heating wire heater; A power source and a temperature controller configured to generate and output a gate trigger voltage in response to a heating temperature set by a user; A heating wire heater driver for supplying a heating current to the heating wire heater in response to the gate trigger voltage to generate heat; A gate trigger voltage detector detecting a gate trigger voltage supplied to the heating line heater driver; An exothermic voltage detector configured to detect and convert an exothermic current supplied to the exothermic wire heater into an exothermic voltage; And A power fuse disconnection unit comparing the gate trigger voltage input from the gate trigger voltage detection unit with the heating voltage input from the heating voltage detection unit, and disconnecting the power fuse according to the comparison result; Power supply fuse disconnection device when a fault occurs in the control rectifier of the heater. The method of claim 14, The gate trigger voltage detector, A rectifier device for detecting the gate trigger voltage, a charging device charged by the gate trigger voltage, and a delay device for smoothing and delaying a signal voltage supplied from the charging device, The heating voltage detection unit, A rectifier for detecting the heating voltage, a charging device charged by the heating voltage, and a delaying device for smoothing and delaying the signal voltage supplied from the charging device. Fuse breaker. The method of claim 14, The power fuse disconnection unit may include a power supply fuse, a heat generating resistor device for disconnecting the power fuse, a first switching device turned on or off by a signal voltage output from the gate trigger voltage detector, the first switching device or the It is composed of a second switching element that is turned on or off by the signal voltage of the heating voltage detection unit, When the signal voltage is output from the heating voltage detector in a state in which the signal voltage is not output from the gate tree voltage detector, the second switching device is turned on so that a current flows to the heating resistor element to generate heat. Power fuse disconnection device in case of control rectifier failure. The method of claim 14, The power fuse disconnection unit may include a power supply fuse, a heating resistor device for disconnecting the power fuse, a switching device turned on or off by a signal voltage output from the gate trigger voltage detector, the switching device or the heating voltage detection unit. Consists of a control rectifier device that is turned on or off by the signal voltage, When the control voltage is turned on by outputting a signal voltage from the heating voltage detector in a state in which the signal voltage is not output from the gate tree voltage detector, a heater is generated by causing a current to flow through the heating resistor element. Power fuse disconnection device in case of rectifier failure.

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