KR100942909B1 - Heating wire controller - Google Patents

Abstract

The present invention relates to a non-electromagnetic wave thermostat and a method of heating wire for bedding, which can make heating and temperature detection non-electromagnetic waves without short-circuit of one end of the heating wire used for a heater such as electric blanket, electric yoke, electric steamer and the like. . In addition, in the present invention, when the heating temperature of the heating wire is adjusted or any point of the heating wire is locally overheated, a magnetic field is not generated in the heating wire without reducing the heat generation amount and controlling the temperature without a separate temperature sensor, and shorting one end of the heating wire. And a thermostat which prevents the generation of leakage electric fields.

According to the present invention, heating and temperature detection can be made non-electromagnetic waves without shorting one end of the heating wire, and there is an effect of blocking harmful electromagnetic waves emitted from the heating wire, and the temperature detection of the electromagnetic shielding non-magnetic heating wire is simplified. It is effective to make it possible. The present invention is provided with a temperature signal voltage detection unit and a temperature control control unit at only one of the heating wires of one of the non-magnetic heating wires, which greatly simplifies the connection between the temperature controller and the heating wire and reduces the production cost.

Description

Electromagnetic shielding thermostat of non-magnetic heating wire {Heating wire controller}

The present invention relates to a non-electromagnetic wave thermostat and a method of heating wire for bedding, which can make heating and temperature detection non-electromagnetic waves without short-circuit of one end of the heating wire used for a heater such as electric blanket, electric yoke, electric steamer and the like. . In addition, in the present invention, when the heating temperature of the heating wire is adjusted or any point of the heating wire is locally overheated, a magnetic field is not generated in the heating wire without reducing the heat generation amount and controlling the temperature without a separate temperature sensor, and shorting one end of the heating wire. The present invention relates to a temperature sensing non-electromagnetic wave heating wire and a temperature controller for bedding, which prevents the occurrence of a leakage electric field.

In the case of a good night's sleep, the bedside conditions such as temperature and humidity serve as important requirements.In the case of general homes, electric beddings and electric heaters such as electric blankets, electric mattresses, and electric steamers are used to maintain the bed temperature properly. Doing. The heating bedding, the heater is built in a heating wire, the power supply to the heating wire generates heat. Therefore, it is essential to configure a temperature controller that senses the temperature around the heating wire and controls the power supply accordingly.

The conventional bedding heating wire has shorted one end of two metal heating wires arranged in parallel, and is equipped with a separate temperature sensing sensor separated from the heating wire to detect temperature. However, the method of separating the temperature sensor and the heating wire has a problem that not only does not detect the temperature of the entire heating wire caused by a short circuit inside the heating wire, but also does not detect local overheating at an arbitrary position. Therefore, when the heating wire is locally overheated or short-circuit and disconnection, there is a problem that a fire and an electric shock may occur.

As another conventional method, a method of detecting a temperature with a third electric wire by adding a separate temperature sensor to an outer circumferential surface or an inner center surface of which two ends are short-circuited among two metal heating wires arranged in parallel is used. However, since the temperature sensor layer and the third metal layer are added to the heating wire without the separation from the heating wire, the thickness of the non-magnetic heating wire is increased so that it cannot be used for thin bedding, and the heating wire is produced. There are problems such as complicated process and rising production cost. In addition, the above-mentioned conventional techniques all have a problem in controlling the temperature of the heating wire, or the thickness of the heating wire has a problem that the utility line is not practical, or does not block harmful electromagnetic waves due to voltage and current.

On the other hand, in relation to heating wires, general magnetic field heating wires used as heating elements in electric bedding, electric mattresses or heating mats, heating devices, and the like, generally, a ventricle made of polyester thread or glass wool, and a spiral in the ventricles A heater coil wound by a wire, an inner insulator coated for insulation on the heater coil of the ventricle outer circumferential surface, a shield wired and grounded in the form of a conductor or a net on the outer circumferential surface of the inner insulator, and an outer coated on the shield Insulator etc. In the above configuration, the heater coil and the shield are electrically connected in series with each end connected to each other, and each of the leading ends thereof is a power input terminal respectively connected to the (+) (-) terminal of the power source.

Since these heating wires cannot detect local overheating and adjust the energization accordingly, there is a risk of fire or burns when tens of meters of heating wires are locally overheated or exceeded a reference temperature at an arbitrary position. The power must be cut off, and a separate temperature detector must be provided for this purpose. In other words, in order to detect the temperature of the long heating wire, there is a cumbersome point in that a plurality of temperature detection devices must be additionally provided at an arbitrary position. There is a problem that the temperature detection device can not be attached to the bedding.

In order to improve the heating line and the temperature control device, the applicant has developed a local overheat detection technology using an NTC thermistor. However, this technique measures the output of the heating line front end in that the heating line measures the output at the rear end. Therefore, the need for a heating wire to detect overheating has emerged.

The present invention has been made to solve the above problems, and provides a temperature controller and a method capable of heating and temperature detection non-electromagnetic waves without short circuiting one end of the heating wire, while maintaining the electromagnetic wave blocking function of the heating wire An object of the present invention is to detect a temperature signal voltage on the power supply side and to allow temperature control.

The configuration of the present invention for achieving the above object is connected to the heating wire including the first and second heating wires and the NTC thermistor or insulating resin disposed between each other, which is output between the power source and the first heating wire A temperature signal voltage detector for detecting a temperature signal voltage; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifier provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires cancel each other to form a magnetic field during temperature detection and heating. Provided is an electromagnetic wave blocking temperature controller of a heating wire.

The temperature signal voltage detector includes a resistor, and the temperature signal voltage is output from the resistor and compared with the temperature control controller.

The temperature signal voltage detector may include: a resistor, a constant voltage diode, and a photo coupler transistor, wherein the temperature signal voltage is output from the photo coupler transistor and compared with the temperature control controller.

The temperature control control unit: a fixed reference voltage generation unit for outputting the reference voltage; A comparison detecting unit comparing the temperature signal voltage with the reference voltage and outputting a driving signal when the temperature signal voltage is higher than the reference voltage; A trigger delay unit which is driven by the driving signal of the comparison detection unit and delays a trigger signal for a predetermined time; And a trigger output unit which outputs a trigger signal for a time delayed by the trigger delay unit.

The insulating resin is characterized by using a resin having a characteristic that the insulating coefficient is sharply dropped in the high temperature region.

The insulating resin is characterized by using a resin having a characteristic in which the insulating coefficient changes in the high temperature region (-).

The temperature control controller may include: a rectifier diode configured to receive and determine a negative phase of the temperature signal voltage; A constant voltage diode comparing the temperature signal voltage with a reference voltage; A transistor for amplifying the compared temperature signal voltage; A charging resistor connected in parallel between the gate and the cathode of the control rectifier; A charge / discharge capacitor connected in series with the gate of the control rectifier; A rectifier diode connected in series with the charge / discharge capacitor to determine a charging current; It characterized in that it comprises a resistor for discharging the charge-discharge capacitor.

According to the present invention, heating and temperature detection can be made non-electromagnetic waves without shorting one end of the heating wire, and there is an effect of blocking harmful electromagnetic waves emitted from the heating wire, and the temperature detection of the electromagnetic shielding non-magnetic heating wire is simplified. It is effective to make it possible.

The present invention is provided with a temperature signal voltage detection unit and a temperature control control unit at only one of the heating wires of one of the non-magnetic heating wires, which greatly simplifies the connection between the temperature controller and the heating wire and reduces the production cost.

In addition, not only the temperature of the entire heating wire generated due to a short circuit but also local overheating at an arbitrary position can be detected, and the surface electric field of the heating wire can be grounded at zero potential.

The objects, features and effects of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. The present invention is a temperature controller in which heating and temperature detection are implemented without electromagnetic waves without shorting one end of the heating wire, and particularly, a configuration for detecting a temperature signal voltage between any one of two heating wires and a power source. Suggest.

1 is a view showing a circuit connection of the present invention, Figure 2 is a diagram showing a simplified view of FIG. 1 and 2, the present invention relates to a temperature transducer connected to a heating line 10, and a temperature controller includes a temperature signal voltage detector 20, a temperature control controller 30, and a control rectifier 18. It includes.

The heating wire 10 used for bedding includes a first heating wire 13 wound on an outer circumferential surface of the insulating core, a first covering 14 surrounding the first heating wire 13, and a second heating wire wound on the outside thereof. 15 and a second coating 16 surrounding the outermost portion. The first coating 14 may use an NTC thermistor (Negative Temperature Coefficient Thermistor) whose resistance value decreases as the temperature increases, or use a constant temperature melt insulating resin. The first heating wire 13 and the second heating wire 15 are arranged side by side or in parallel with each other.

When the AC input power is turned on, the line half cycle during the AC cycle does not output a change in the temperature resistance value of the first coating 14 between the first heating wire 13 and the second heating wire 15, but instead of outputting the first resistance 14. The temperature signal voltage detection unit 20 between the heating wire 13 and the power supply side outputs it in advance.

The temperature detection signal current flows through the first heating wire 13 and the second heating wire 15 when the U-turn is passed through the first heating wire 13 in the first coating 14 and flows back to the second heating wire 15. Since the detection signal currents are opposite to each other, the magnetic field cancels and the temperature detection signal current flows in a magnetic field.

The temperature control controller 30 outputs a control signal when the temperature voltage output in front of the first heating wire is greater than the reference voltage. In the present exemplary embodiment, the temperature control controller 30 includes a fixed reference voltage generator 31 for outputting a reference voltage and a comparison detector 32 for outputting a driving signal when the temperature voltage is higher than the reference voltage by comparing the temperature voltage with the reference voltage. ), A trigger delay unit 33 driven by the drive signal of the comparison detection unit 32 to delay the trigger signal for a predetermined time, and a trigger output for outputting a trigger signal for a time delayed by the trigger delay unit 33. And part 34.

The control rectifiers 18 and 19 allow the heating current to flow U-turn to the power supply side through the other end and one end of the first heating wire 13 from the opposite end of the second heating wire 15 connected to the power supply when conducting by the trigger signal. . In the present embodiment, the control rectifier includes a U-turn rectifier 18 and a control rectifier 19 for a heating current u-turn.

The heating current u-turn rectifier 18 has a cathode connected to the other end of the first heating wire 13 and an anode connected to the second heating wire 15 on the same side. In this embodiment, a diode is used.

The control rectifier 19 has an anode connected in parallel with the temperature signal voltage detector 20 at one end of the first heating wire 13 and a cathode connected to the power supply side, and is turned on by a trigger signal of the trigger input unit 17. . As the control rectifier 19, it is most preferable to use a silicon-controlled rectifier (hereinafter referred to as SCR) for power control.

The trigger delay unit 33 starts at the temperature detection cycle of the AC power cycle and is maintained until the control rectifier 19 is turned on in the heating cycle. At this time, the control rectifier 19 is turned on at the zero point to control power. Is characteristic.

The magnetic field-free heating operation, when the control rectifier 19 is turned on by the trigger signal output of the temperature control controller 30, the second heating line 15, the heating current U-turn rectifier 18, the first heating line ( 13) and a heating current flows to the control rectifier 19 to heat the heating wire.

NTC thermistor or constant temperature melting insulation resin is used as the first coating 14. When the first coating 14 is heated to change the physical properties while changing the physical properties, the temperature control controller 30 detects this. In the normal state, the set current flows through the heating line to perform the heating operation, and in the abnormal state, the heating is interrupted to stop the heating. In particular, the hot melt insulating resin is to use a resin having a characteristic that the insulation coefficient is sharply changed or negative (-) in the high temperature range.

3 is a view schematically showing a state when a heating current flows. Referring to FIG. 3, when the AC power is negatively applied and the trigger input unit 17 turns on the control rectifier 19, the power current flows into the second heating wire 15 and the heating current U-turn rectifier 18. Through again comes back to the first heating wire (13). When the current flows through the anode of the control rectifier 19, the heating line is heated, and the current value is determined as the internal resistance of the first heating line 13 and the second heating line 15.

When the heating wire is heated, the impedance of the NTC thermistor, which is the first coating 14, becomes low, or the insulation coefficient of the constant-temperature molten insulating resin drops sharply or changes to negative, so that the AC power supply has a positive phase for the next half cycle. During this time, the temperature voltage is lowered. Therefore, when the temperature voltage is lower than the reference voltage, the trigger signal is not output, and thus, the control rectifier 19 does not operate and the heating is stopped.

4 is a diagram simply showing a state when a temperature signal is detected. Referring to FIG. 4, during the initial half wave, it is determined whether or not a voltage is lost while determining whether there is a voltage. The temperature signal voltage detection unit 20 detects a temperature signal between the first heating wire 13 and the power source, that is, before the current is input to the heating wire 10, and a resistor 21 may be used for this purpose.

If the constant temperature melt insulation resin or NTC thermistor of the first coating 14 is damaged or the physical properties change due to the high temperature, the signal voltage is lost while the insulation resin or NTC thermistor internal resistance value R is changed. Ensure that no heating current flows during the next half wave.

Cold-melt insulation resin is made of PP, PE, PVC, nylon, silicon and so on. When the heating wire is overheated and rises above the limit temperature, the physical properties change.Because the internal insulation softens and the insulation falls sharply, In the case where an effect such as an increase in leakage current or change in dielectric constant occurs, this is referred to as insulation performance or insulation coefficient being decreased or negative. Therefore, according to the sensitivity of the abnormal state detection of the temperature control controller 30, when the hot melt insulating resin affects the ambient voltage while changing the physical properties and the insulation coefficient decreases or becomes negative, no more heating current Because it blocks the, it will act as a safety device.

On the other hand, in the case of the NTC thermistor, when a power source having a positive phase is applied, the temperature signal is first detected by the resistor 21, and the temperature regulation control unit 30 compares the temperature signal. It is applied to the NTC thermistor between (13) and the second heating wire (15). The potential of both ends of the NTC thermistor (the first heating wire and the second heating wire) may be output as a temperature voltage between the rectifier (not shown) and the second heating wire 15 for detecting the temperature voltage, but this is the content of already developed technology.

The temperature voltage is output in inverse proportion to the temperature, and the operating current operated during temperature detection flows a very small current of several mA or less. 6 shows the impedance change of the heating wire and the NTC thermistor (nylon 12 series) according to the temperature change. The first heating wire 13 and the second heating wire 15 are utilized as electrodes of the NTC thermistor, and simultaneously output the surface temperature of the entire length of the heating wire and locally overheated at any portion of the heating wire.

The comparison detecting unit 32 compares the temperature voltage output from the front end of the first heating wire 13 with the reference voltage output from the fixed reference voltage generating unit 31, and if the temperature voltage is higher than the reference voltage, the trigger delay unit 33 is used. Drive. The trigger delay unit 33 causes the trigger output unit 34 to delay the trigger signal for a predetermined time, and the trigger output unit 34 outputs the trigger signal for the time delayed by the trigger delay unit 33.

When the heating wire is heated, the impedance of the NTC thermistor is lowered, so the temperature voltage is lowered during the next half cycle in which the AC power supply has a positive phase. Therefore, when the temperature voltage is lower than the reference voltage, the trigger signal is not output, and thus, the control rectifier 19 does not operate and the heating is stopped.

Since the heating wire repeats heating after detecting the temperature first every half cycle of the input power supply as shown in FIG. 7, the heating wire can be heated after confirming the internal short circuit and abnormality of the heating wire.

Fig. 5 is a diagram showing another state when the temperature signal is detected. Referring to FIG. 5, the resistor 21, the photocouple transistor 22, and the constant voltage diode 23 are connected in series to the temperature signal voltage detector 20 to output the temperature signal voltage from the photocouple transistor 22. Can also be used.

FIG. 7 is a view for explaining a process of detecting a temperature of a heating wire and heating operation according to an AC power input and forming a magnetic field. Referring to FIG. 7, as shown in (a), the AC input power is first applied during the shelf cycle to detect the signal voltage, and when there is no abnormality, the heating voltage is applied during the subsequent half cycle. After that, a voltage for determining abnormality is input again for half a cycle.

Referring to the magnetic field phase (b) at this time, the half cycle upper side is a half wave voltage detection current for determining whether the first heating wire 13 is abnormal, and the lower half cycle is a half wave voltage detection current for determining whether or not the second heating wire 15 is abnormal. The phases of the magnetic fields are opposite to each other. The upper half of the next half cycle is the heating current of the first heating wire 13, and the lower half is the heating current of the second heating wire 15. Similarly, the phases of the magnetic fields are opposite to each other. Therefore, the electric magnetic fields inside the heating wire cancel each other out, and the first and second heating wires become purely magnetic free. Therefore, harmful waves to the human body are not generated in all processes in which abnormality determination and heating are repeated.

8 is a diagram for illustrating an embodiment of another circuit configuration of the present invention. Referring to FIG. 8, the temperature signal voltage detection unit 20 includes a resistor 21, a photocouple transistor 22, and a constant voltage diode 23, and the signal voltage output from the photocouple transistor 22 is temperature controlled. It is input to the controller 30. Reference numeral 09 denotes an overcurrent protection resistor. The temperature signal voltage detection unit 30 may include a temperature control unit through a microcomputer or a pulse width control method, a temperature control unit power supply unit, a display output unit, an operation input unit, or the like.

Fig. 9 is a diagram showing an embodiment of still another circuit configuration of the present invention. 9, the diode 1 and the constant reference voltage generator 31 are connected to the resistance 21 of the temperature signal voltage detector 20, and the comparison detector 32 is connected to the fixed reference voltage generator 31. PNP transistor 3 is provided. The trigger delay unit and the output units 33 and 34 are configured by connecting the charge / discharge capacitor 6 provided between the resistors 4 and 5, the rectifier diode 7 and the resistor 8 to each other.

10 and 11 are actual operating waveform diagrams according to the circuit configuration of the present invention. 10 and 11, a is the input power waveform, b is the temperature detection voltage and the reference voltage, c is the current of the PNP transistor, d is the capacitor potential of the trigger delay, e is the capacitor of the trigger delay Is the discharge time, and f is the heating current waveform of the heating wire.

When the temperature of the heating wire 10 is low and the resistance value of the NTC thermistor of the first coating 14 is high, the temperature signal voltage value at the resistor 21 is low, and this voltage is fixed through the diode 1 through the fixed reference voltage. It flows through the constant voltage diode 2 of the generator 31 to the base of the PNP transistor 3 of the comparison detector 32, and if it is lower than the potential difference of the constant voltage diode 2 for temperature signal voltage comparison, the comparison detector 32 When the PNP transistor 3 is turned off and is turned off, and the PNP transistor 3 is turned off, the power supply voltage is charged through the diode 7 and the resistor 8 while charging the resistor 5 and the capacitor 6. 6) causes the operation waveforms c and d in FIG. 11 to flow during the half cycle period.

In the next temperature detection cycle, when the charging cycle of the condenser 6 ends, the charging voltage of the condenser 6 starts to discharge through the gate of the control rectifier 19 and the discharge resistor 4 as the heating cycle. The heating cycle voltage of the power source is turned on, flows from one end of the second heating line 15 to the first heating line 13 through the U-turn rectifier 18 connected to the other end, and to the power supply through the control rectifier 19 to FIG. , f flows with the operating waveform.

Next, when the heating current flows and the heating wire is heated, the temperature of the heating wire is high and the resistance value of the NTC thermistor of the first coating 14 is lowered. When the voltage across the resistor 11 increases and is higher than the potential difference of the constant voltage diode 2 for the temperature signal voltage comparison, the PNP transistor 3 of the comparison detecting unit 32 is turned on, and when the PNP transistor 3 is turned on, the power supply voltage is compared. Current flows through the PNP transistor 3, the diode 7, and the resistor 8 of the detector 32 to prevent the capacitor 6 from being charged, and the control rectifier 19 is turned off to operate waveforms e and f of FIG. 10. As such, the heating current does not flow.

Temperature can be automatically adjusted through the repetitive operation of such a circuit, and heating can be appropriately selected using the resistor 11 as a variable resistor.

1 is a view showing a circuit connection of the present invention.

FIG. 2 is a diagram schematically illustrating FIG. 1.

3 is a view schematically showing a state when a heating current flows.

4 is a diagram simply showing a state when a temperature signal is detected.

Fig. 5 is a diagram showing another state when the temperature signal is detected.

6 is a view showing the characteristics of a thermistor whose resistance value changes with temperature and a heating wire used in the temperature controller of the present invention.

FIG. 7 is a view for explaining a process of detecting a temperature of a heating wire and heating operation according to an AC power input and forming a magnetic field.

8 is a diagram for illustrating an embodiment of another circuit configuration of the present invention.

Fig. 9 is a diagram showing an embodiment of still another circuit configuration of the present invention.

10 and 11 are actual operating waveform diagrams according to the circuit configuration of the present invention.

<Description of Symbols for Main Parts of Drawings>

1: diode 2: constant voltage diode

3: transistor 4, 5, 8: resistor

6: charge / discharge capacitor 7: diode

10: heating wire 13: first heating wire

14: 1st coating 15: 2nd heating wire

16: second coating 17: trigger input unit

18: U-turn rectifier 19: control rectifier

20: temperature signal voltage detector 21: resistance

22: photocouple transistor 23: constant voltage diode

30: temperature cut control unit 31: fixed reference voltage generator

32: comparison detection unit 33: trigger delay unit

34: trigger output unit

Claims (7)

delete A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The temperature signal voltage detection unit: Include resistance, The temperature signal voltage is output from the resistance is electromagnetic wave blocking temperature controller of the heating line, characterized in that compared in the temperature control controller. A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The temperature signal voltage detection unit: Includes resistors, constant voltage diodes and photocouple transistors, The temperature signal voltage is output from the photocoupler transistor is compared with the temperature control controller, electromagnetic wave blocking temperature controller of the heating line. A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The temperature control unit: A fixed reference voltage generator for outputting the reference voltage; A comparison detecting unit comparing the temperature signal voltage with the reference voltage and outputting a driving signal when the temperature signal voltage is higher than the reference voltage; A trigger delay unit which is driven by the driving signal of the comparison detection unit and delays a trigger signal for a predetermined time; And And a trigger output unit for outputting a trigger signal for a time delayed by the trigger delay unit. A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The insulating resin electromagnetic shielding temperature controller of the heating wire, characterized in that for use in the resin having a characteristic that the insulating coefficient is sharply dropped in the high temperature region. A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The insulation resin is electromagnetic radiation blocking temperature controller of the heating wire, characterized in that the resin having a characteristic that the insulation coefficient is changed to negative (-) in the high temperature region. A temperature signal voltage detection unit connected to the first and second heating wires arranged next to each other and a heating wire including an NTC thermistor or an insulating resin therebetween; A temperature regulation control unit for outputting a temperature control signal by comparing the temperature signal voltage detected by the temperature signal voltage detection unit with a reference voltage; And a control rectifying portion provided between an end of the first heating wire and an end of the second heating wire, wherein the first and second heating wires offset magnetic fields from each other during temperature detection and heating to form a magnetic field. In the regulator, The temperature signal voltage detection unit detects a temperature signal voltage output between a power supply and a tip of the first heating wire, The temperature control unit: A rectifier diode for determining and accepting the negative phase of the temperature signal voltage; A constant voltage diode comparing the temperature signal voltage with a reference voltage; A transistor for amplifying the compared temperature signal voltage; A charging resistor connected in parallel between the gate and the cathode of the control rectifier; A charge / discharge capacitor connected in series with the gate of the control rectifier; A rectifier diode connected in series with the charge / discharge capacitor to determine a charging current; And a resistance for discharging the charge / discharge capacitor.

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