JP2006190638A5 - - Google Patents

Claims (44)

The first and second heating wires arranged side by side and the heating wire including the NTC thermistor are connected,
A temperature adjustment control unit that outputs a temperature control signal with reference to a reference voltage, the temperature signal voltage output from the first heating wire;
Control that the heating current returns from the opposite end of the second heating wire connected to the power source to the power source side through the other end and one end of the first heating wire when conducting by the control of the temperature control unit Including a rectifying unit,
A non-electromagnetic wave temperature controller for a heating wire, wherein the heating wire cancels the magnetic field to form a magneticless field during temperature detection and heating. The non-electromagnetic temperature controller for a heating wire according to claim 1, further comprising a temperature voltage adjusting unit for adjusting a temperature detection voltage approved at one end of the first heating wire. The temperature control unit is
A reference voltage generator for outputting the reference voltage;
If the temperature voltage is higher than the reference voltage, a comparison detection unit that outputs the drive signal with reference to the reference voltage, the temperature voltage;
A trigger delay unit that is driven by a drive signal of the comparison detection unit and delays the trigger signal for a predetermined time;
The non-electromagnetic wave temperature controller for a heating wire according to claim 2, further comprising a trigger output unit that outputs a trigger signal during a time delayed by the trigger delay unit. The control rectifier is
The non-electromagnetic wave temperature controller for a heating wire according to claim 2, further comprising a heating current U-turn rectifier between the other end of the first heating wire and the second heating wire. The control rectifier is
And a control rectifier having an anode connected to one end of the first heating wire in parallel with the temperature voltage controller, a cathode connected to a power source, and turned on by a control signal of the temperature controller. The non-electromagnetic wave temperature controller for a heating wire according to claim 4. The temperature voltage adjustment unit includes:
A resistor with one end connected to the power source;
The non-electromagnetic wave temperature controller for a heating wire according to claim 2, comprising a variable resistor for temperature detection adjustment connected in series between the other end of the resistor and one end of the first heating wire. The temperature voltage adjustment unit includes:
First and second resistors connected in series;
A variable resistor connected between the first resistor and the second resistor;
Including a third resistor having one end connected to the power source and the other end connected to the movable piece of the variable resistor;
One side of the first resistor is connected to the first heating wire, one side of the second resistor is connected to a second heating wire on the same side, and input impedance is matched by adjusting the variable resistance value. The non-electromagnetic wave temperature controller for a heating wire according to claim 2. 3. The non-electromagnetic wave temperature controller for a heating wire according to claim 2, wherein the temperature control unit and the gate of the control rectifier are connected to a photocoupler SCR. The temperature control unit is
A discharge resistor connected in series to the gate of the control rectifier;
A rectifier diode connected in series with the discharge resistor;
A capacitor connected in parallel between the gate bias resistor and the rectifier diode;
A comparison zener diode;
Gate over-input limit resistor,
An SCR having an anode connected to a capacitor and a gate connected to the gate over-input limit resistor;
An SCR gate bias resistor connected in parallel between the gate over-input limit resistor and the gate of the SCR;
The non-electromagnetic wave temperature controller for a heating wire according to claim 2, further comprising a charging current limiting resistor connected between the anode of the SCR and the capacitor. The gate of the control rectifier is insulated from the photocoupler SCR, the light emitting side of the photocoupler SCR is connected in series with the discharge resistor, and the receiver side of the photocoupler SCR is connected in series with the trigger resistor to the gate and anode of the control rectifier. The non-electromagnetic wave temperature controller for a heating wire according to claim 9, wherein the temperature controller is connected between them. A first diode connected in parallel to the first heating wire and in the reverse direction of the heating current;
A zener diode connected in parallel with the heating current U-turn rectifier;
And further comprising a reverse overcurrent safety device composed of the second heating wire and a second diode connected in parallel in the reverse direction of the heating current,
3. The non-electromagnetic wave temperature controller for a heating wire according to claim 1, wherein when an overcurrent is generated due to a short circuit of the control rectifier, the fuse is cut off through the reverse overcurrent safety device. A grounding point indicator connected to one end of the second heating wire that is grounded;
The non-electromagnetic wave temperature control of the heating wire according to claim 1 or 2, further comprising an inspection test terminal for setting the grounding point indicator at an extinguishing position and cutting off a surface electric field of the heating wire. vessel. A temperature detection process for detecting a temperature voltage output from the first heating wire at the opposite end of the heating wire, one end of which is connected to the power source;
If the output temperature voltage is greater than a reference voltage, a temperature adjustment process for outputting a control signal;
When conducting by the control signal, there is no heating wire including a heating process in which current flows from the opposite end of the second heating wire connected to the power source to the power source side through the other end and one end of the first heating wire. Electromagnetic temperature control method. The method of claim 13 , further comprising adjusting a temperature detection voltage approved at one end of the first heating wire. The temperature adjustment process includes:
Outputting the reference voltage;
Outputting the drive signal if the temperature voltage is higher than the reference voltage by comparing the temperature voltage with the reference voltage;
Driven by the driving signal and delaying the trigger signal for a certain period of time;
The method of claim 13 , further comprising: outputting a trigger signal during the delay time. A first electrothermal layer coupled to one of the terminals of the power source;
A thermistor layer that winds and coats the first electrothermal layer;
A second electrothermal layer wound around an outer peripheral surface of the thermistor layer and having one end connected to the other terminal of the power source;
A temperature-sensing non-electromagnetic wave heating wire comprising a thermistor layer and an insulating layer that winds and insulates the outside of the second electrothermal layer. The first electrothermal layer is
The core yarn in the center,
Is spirally wound on the outer peripheral surface of the core yarn, includes a heating wire of which one end is connected to either the one terminal of the power supply, according to claim 16, wherein when energized through the electrical heating wire Temperature sensing non-electromagnetic heating wire. The temperature according to claim 17 , further comprising a conductive coating layer that is coated on an outer peripheral surface of the second electrothermal layer and winds around the second electrothermal layer between the second electrothermal layer and the insulating layer. Sensitive electromagnetic wave heating wire. The temperature-sensitive non-electromagnetic wave heating wire according to claim 17 or 18, wherein the second electrothermal layer includes a thin metal plate, and the thin metal plate is spirally wound around an outer peripheral surface of the thermistor layer. The temperature-sensitive non-electromagnetic wave heating wire according to claim 17 or 18, wherein the second electrothermal layer includes a metal shield body, and the metal shield body winds around an outer peripheral surface of the thermistor layer. The temperature-sensitive non-electromagnetic wave heating wire according to claim 16, wherein the first electrothermal layer includes an electrothermal conducting wire having one end connected to one terminal of a power source. The temperature according to claim 21 , further comprising a conductive coating layer that is coated on an outer peripheral surface of the second electric heating layer and winds around the second electric heating layer between the second electric heating layer and the insulating layer. Sensitive electromagnetic wave heating wire. The temperature-sensitive non-electromagnetic wave heating wire according to claim 21 or 22, wherein the second electrothermal layer includes a thin metal plate, and the thin metal plate is spirally wound around an outer peripheral surface of the thermistor layer. The temperature-sensitive non-electromagnetic wave heating wire according to claim 21 or 22, wherein the second electrothermal layer includes a metal shield body, and the metal shield body winds around an outer peripheral surface of the thermistor layer. The other end of the second electrothermal layer is connected to one side of a second unidirectional rectifier, the other end of the heating wire of the first electrothermal layer is connected to the other side of the second unidirectional rectifier, A heating current supplied from the power source to one end side of the second electrothermal layer is input to the other end side of the heating wire of the first electrothermal layer through the second unidirectional rectifier so as to return to the power source. The temperature-sensitive non-electromagnetic wave heating wire according to claim 17 or 18, wherein The other end of the second electrothermal layer is connected to one side of a second unidirectional rectifier, and the other end of the electrothermal conductor of the first electrothermal layer is connected to the other side of the second unidirectional rectifier, A heating current supplied from the power source to one end side of the second electrothermal layer is input to the other end side of the electrothermal conducting wire of the first electrothermal layer through the second unidirectional rectifier so as to return to the power source. The temperature-sensitive non-electromagnetic wave heating wire according to claim 21 or 22, A first electrothermal layer coupled to one of the terminals of the power source;
A thermistor layer that is wound around the first electrothermal layer; and
A second electrothermal layer wound around the thermistor layer and having one end coupled to the other terminal of the power source;
A temperature-sensitive non-electromagnetic wave heating wire comprising the thermistor layer and a conductive coating layer wound outside the second electrothermal layer. 28. The temperature-sensitive non-electromagnetic wave heating wire according to claim 27, wherein the conductive coating layer is made of a conductive synthetic resin material, and is entirely wound so that the thermistor layer and the second electric heating layer are not exposed to the outside. . The first electrothermal layer is
Including a central core yarn, and a heating wire spirally wound around the outer peripheral surface of the core yarn, one end of which is connected to one terminal of a power source, and is energized through the heating wire. The temperature-sensitive non-electromagnetic wave heating wire according to claim 27 . 28. The temperature-sensing non-electromagnetic wave heating wire according to claim 27, wherein the first electrothermal layer includes an electrothermal conducting wire having one end connected to one terminal of a power source. The temperature-sensitive non-electromagnetic wave heating wire according to claim 29 or 30, wherein the second electrothermal layer includes a metal thin plate, and the metal thin plate is spirally wound around an outer peripheral surface of the thermistor layer. The temperature-sensitive non-electromagnetic wave heating wire according to claim 29 or 30, wherein the second electrothermal layer includes a metal shield body, and the metal shield body winds around an outer peripheral surface of the thermistor layer. The other end of the second electrothermal layer is connected to one side of a second unidirectional rectifier, the other end of the heating wire of the first electrothermal layer is connected to the other side of the second unidirectional rectifier, A heating current supplied from the power source to one end side of the second electrothermal layer is input to the other end side of the heating wire of the first electrothermal layer via the second unidirectional rectifier and returned to the power source. 30. The temperature-sensing non-electromagnetic wave heating wire according to claim 29 . The other end of the second electrothermal layer is connected to one side of a second unidirectional rectifier, and the other end of the electrothermal conductor of the first electrothermal layer is connected to the other side of the second unidirectional rectifier, A heating current supplied from the power source to one end side of the second electrothermal layer is input to the other end side of the electrothermal conducting wire of the first electrothermal layer through the second unidirectional rectifier so as to return to the power source. The temperature-sensitive non-electromagnetic wave heating wire according to claim 30, wherein A first unidirectional rectifier is further included, and the other end of the heating wire of the first heating layer is connected to the first unidirectional rectifier and outputs a voltage output from the other end of the heating wire. 26. The temperature-sensitive non-electromagnetic heating wire according to claim 25 . The first unidirectional rectifier is further included, and the other end of the heat conducting wire of the first electrothermal layer is connected to the first unidirectional rectifier and outputs a voltage output from the other end of the heat conducting wire. 27. The temperature-sensitive non-electromagnetic wave heating wire according to claim 26 . A first unidirectional rectifier is further included, and the other end of the heating wire of the first heating layer is connected to the first unidirectional rectifier and outputs a voltage output from the other end of the heating wire. 34. The temperature-sensitive non-electromagnetic heating wire according to claim 33 . Further including a first unidirectional rectifier, the other end of the electric heating wire of the first electrothermal layer is connected to the first unidirectional rectifier and outputs a voltage output from the other end of the electric heating wire. The temperature-sensing non-electromagnetic wave heating wire according to claim 34, wherein: The second electrical heating layer, claims wherein encompass leads or sheet metal wound in thermistor layer, characterized in that it comprises a metal plate winding outside of the said thermistor layer leads or sheet metal The temperature-sensitive non-electromagnetic wave heating wire according to 17 or 18 . The second electrical heating layer, claims wherein encompass leads or sheet metal wound in thermistor layer, characterized in that it comprises a metal plate wrapped outside of the leads or metal sheet and the thermistor layer The temperature-sensitive non-electromagnetic wave heating wire according to 21 or 22 . The second electrical heating layer, claims wherein encompass leads or sheet metal wound in thermistor layer, characterized in that it comprises a metal plate winding outside of the said thermistor layer leads or sheet metal The temperature-sensitive non-electromagnetic wave heating wire according to 29 or 30 19. The electromagnetic wave according to claim 17 , further comprising a metal plate film having a metal plate on one side of the insulating layer and an insulating layer formed on a back surface of the metal plate. Cut off heating wire. 23. The electromagnetic wave according to claim 21 , further comprising a metal plate film having a metal plate on one side thereof and an insulating layer formed on a back surface of the metal plate. Cut off heating wire. The metal plate film according to claim 29 or 30 , further comprising a metal plate on one side of the conductive coating layer, and a metal plate film having an insulating layer formed on a back surface of the metal plate. Electromagnetic wave blocking heating wire.