KR200276482Y1 - Temperature detector using non-magnetic field heating wire - Google Patents

Abstract

The temperature detector using the non-magnetic thermosensitive wire of the present invention reads the heating wire 5, the thermal sensor unit 8 whose resistance value is lowered in proportion to the temperature when the heating wire is heated, and the value change of the thermal sensor unit. The sensing shield lead wire 6 in the form of a mesh and a thermal conductor made of an insulating sheath 7 surrounding the sensing shield lead wire are used as electrodes for the electrode. In addition, by using a transcore (1) in which two cores are joined side by side, an end-side current detection coil (3) connected in series between a sensing shielded lead wire and a heating wire at one end of the heating core to one core of the transcore. At the other end of the transcore, wind the input side current detection coil (4) connected in series between the heating wire and the AC power supply at the other end of the heating core. In addition, the output coil 2 is wound around the coupling portion of the transcore, and the end side current detection coil and the input side current detection coil have a direction such that magnetic flux at the coupling portion of the transcore is canceled when the current flowing through both coils is the same. Wind up In addition, the insulation wire core 9 may be further provided inside the heating wire, and the heating wire may have a configuration in which the insulation wire is wound spirally. As the thermal sensor unit, a nylon thermistor may be used. In addition, the output coil is connected to the power control unit of the thermostat, it can be used in the thermostat to cut off the power supply to the thermal line when the current flows in the output coil. In the thermal wire, the sensing shield lead wire may be used in the form of a net or in a spiral to keep the resistance of the sensing shield lead wire lower than that of the heating wire.

Description

TEMPERATURE DETECTOR USING NON-MAGNETIC FIELD HEATING WIRE}

The present invention relates to a temperature detector using a non-magnetic thermosensitive wire, and more particularly, to a temperature detector using a non-magnetic thermosensitive wire for sensing temperature in bedding using a thermal wire of a structure in which an electric magnetic field is blocked.

Current temperature detection of heating wire is a temperature detection method using resistance value or impedance change value of nylon thermistor between heating wire and helical sensing wire to control applied power of heating wire. However, only half wave of AC AC is applied.

The reason for this is that a short circuit between the heating wire and the heating wire and the sensing wire due to heat must be detected between the heating wire and the sensing wire during the AC cycle.

Therefore, twice as much current flows as the radio wave use, and the humming noise is generated by this half-wave overcurrent.

In addition, there is no non-magnetic wire using thermal wires, and the non-magnetic wire of Registration Utility Model No. 108921 is not a thermal wire method, but a three-layer non-magnetic wire that is wound with a temperature sensing resistance wire on a heating wire and a shield wire is formed thereon.

No. 186614 is proposed to block electromagnetic waves by allowing two wires to be in close proximity to each other in the same theory as an AC input cord wire so that current flows in opposite directions to inner and outer conductor wires of a heating wire. However, the sensor that detects temperature is a simple hot wire that is not configured.

In both cases, there is a need for a device capable of easily detecting overheating or a short circuit between two lines.

The present invention has been made in view of this point, and an object thereof is to provide a temperature detector capable of detecting overheating without increasing the thickness of the thermal wire.

Another object of the present invention is to easily detect overheating or short-circuit in a non-magnetic line having a configuration that can block electromagnetic waves by allowing a current to flow in a direction opposite to each other in a heat wire that is an inner layer of the heat ray and a sensing shielded lead that is an outer layer of the heat ray. It is to provide a temperature detector that can be.

1 is a view showing the configuration of the electric blanket temperature detector according to the present invention.

2 is a view showing the structure of the thermal wire used in the electric blanket of the present invention.

Figure 3 is an equivalent circuit diagram showing the current distribution in the thermal line used in the electric blanket of the present invention.

4 is a view showing a preferred use of the present invention.

<Description of Symbols for Main Parts of Drawings>

1: transcore, 2: output coil,

3: end side current detection coil, 4: input side current detection coil,

5: hot wire, 6: network type shielding lead wire,

7: insulated jacket, 8: thermal sensor unit (nylon thermistor),

9: Insulation thread core.

In the magnetic field-free thermal wire used for the temperature detector of the present invention, a thermal sensor unit having a low resistance value in proportion to temperature on a heating wire, a sensing shield lead wire surrounding the thermal sensor part in the form of a network, and an insulation surrounding the sensing shield lead wire Use a thermal wire made of an outer sheath. In addition, by using a transcore of two cores bonded side by side, the end current detection coil connected in series between the sensing shielded lead wire and the heating wire at one end of the heating wire to one core of the transcore, At the other end of the coil, wind the input side current detection coil connected in series between the heating wire and the AC power supply at the other end of the heating wire. In addition, the output coil is wound around the coupling portion of the transcore, and the end side current detection coil and the input side current detection coil are wound in a direction such that the magnetic flux at the coupling portion of the transcore is canceled when the current flowing through both coils is the same. In addition, the insulation wire core may be further provided inside the heating wire, and the heating wire may have a configuration in which the insulation wire is wound spirally. As the thermal sensor unit, a nylon thermistor may be used. In addition, the output coil is connected to the power control unit of the electric blanket, it can be configured to cut off the power supply to the electric blanket when a current flows in the output coil.

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

1 is a view showing the configuration of the electric blanket temperature detector according to the present invention.

The magnetic field-free thermal wire used in the temperature detector according to the present invention used for the electric bedding is a heating wire 5 spirally wound around the insulation chamber core 9, the insulation chamber core 9, and the heating wire from the center. (5) is wrapped around the thermal sensor unit 8 made of a nylon thermistor or the like, the resistance value is lowered in proportion to temperature, and the sensing shielded lead wire (6) surrounding the thermal sensor unit 8 in the form of a net; And an insulating sheath 7 surrounding the sensing shield lead wire 6.

In addition, at one end of the heating wire 5, the sensing shield lead wire 6 is connected to the ground, and AC power is applied to the heating wire 5 through the input side current detection coil 4. At the other end of the heating wire 5, the sensing shield lead wire 6 and the heating wire 5 are connected to each other via the end side current detecting coil 3.

Therefore, the current by the AC power applied to the heating wire (5) flows in the opposite direction in the heating wire (5) and the sensing shield lead wire 6, the electromagnetic wave is blocked by the ground connected to the sensing shield lead wire (6) Has

On the other hand, the drawing shows a case in which the heating wire 5 is wound spirally in the insulating chamber core 9, the heating wire 5 is positioned in place of the insulating chamber core 9 without using the insulating chamber core (9) It is also possible to configure to.

The end side current detection coil 3 and the input side current detection coil 4 are wound around both cores of the trans core 1 of the form in which two cores are joined from the side. At this time, both current detection coils 3 and 4 are wound in the same direction as shown in the drawing. In the trans core 1, the output coil 2 is wound around the coupling part, which is a site where two cores are joined at the side. Since both current detection coils 3 and 4 are wound in the same direction, when the amount of current flowing through both current detection coils 3 and 4 is the same, the magnetic flux flowing in the coupling portion of the transcore 1 is equal to the amount. They are the same and the directions are reversed to cancel Therefore, no current is induced into the output coil 2. On the other hand, when the amount of current flowing through both current detecting coils 3 and 4 is not the same, the amount of magnetic flux flowing in the coupling portion of the transcore 1 is different, so that the magnetic field is not completely canceled and is applied to the output coil 2. Will induce current.

Next, with reference to FIGS. 2 and 3, the case where the amount of current flowing through the end-side and input-side current detection coils 3 and 4 varies. Figure 2 is a view showing the structure of the thermal line used in the electric blanket of the present invention, Figure 3 is an equivalent circuit diagram showing the current distribution in the thermal line used in the electric blanket of the present invention.

In FIG. 3, the resistors H1, H2, and H3 are equivalent resistances of each part when the heating wire 5 is arbitrarily divided into three parts, and the resistors r1, r2, r3, and r4 are the heating wires 5 and the sensing in the above three parts. The equivalent resistance of the shielded lead wire 6 is shown.

In the normal state, since the resistance value of the thermal sensor unit 8 is very high, the resistors r1 to r4 can be considered to be almost open. Therefore, the current Ia from the AC power supply and the current Ia between the heating wire 5 and the sensing shield lead wire 6 at the termination point are almost the same. Therefore, as described above, in the normal state, the current flowing through the end side current detection coil 3 and the input side current detection coil 4 is almost the same, so that the magnetic flux and the input side current detection by the current flowing through the end side current detection coil 3 are almost identical. The magnetic flux caused by the current flowing through the coil 4 is canceled at the coupling portion of the transcore 1 so that no current is induced into the output coil 2.

On the other hand, let's look at the operation when a certain portion of the thermal wire is overheated for some reason. For example, in FIG. 3, when the portion corresponding to the resistance r2 is overheated, the resistance value of the thermal sensor unit 8 decreases in proportion to temperature, so that the resistance value of the resistance r2 becomes relatively low. Therefore, the current i2 flowing to the resistor r2 increases, and Ia becomes lower by that amount. That is, the current Ia flowing in the end side current detection coil 3 is lower than the current I flowing in the input side current detection coil 4, so that the magnetic flux caused by the current flowing through the end side current detection coil 3 and the input side current detection coil 4 The magnetic flux caused by the current flowing through the?) Is not canceled at the coupling portion of the transcore 1. Therefore, the current flows into the output coil 2 by the magnetic flux flowing in the coupling portion of the transcore 1.

Therefore, when a certain portion of the thermal line is overheated, unlike the normal case, current flows in the output coil 2, so that it may be sensed to cut off the input power.

Meanwhile, a case in which a specific portion of the thermal sensor unit 8 of the thermal wire is broken and the sensing shield lead wire 6 and the heating wire 5 are short-circuited in the middle of the thermal wire, will have any one of r1 to r4 shorted in FIG. 3. As is the case, Ia has a significantly lower current than I or no current at all. Therefore, a remarkable difference occurs between the magnetic flux caused by the current flowing through the end side current detecting coil 3 and the magnetic flux caused by the current flowing through the input side current detecting coil 4 so that the magnetic flux remains in the coupling portion of the transcore 1. do. Therefore, a current flows into the output coil 2 by the magnetic flux flowing in the coupling portion of the transcore 1.

4 is a view showing a preferred use of the temperature detector of the present invention. In the drawing, the power supply unit is a part for generating a power source used in the electric blanket, the power control unit is a part for adjusting the temperature by controlling the current provided to the thermal line of the electric blanket, the temperature detection unit is for detecting the temperature of the thermal line Part.

In Fig. 4, the output side of the output coil 2 is connected to a temperature detector to detect the temperature by the current from the output coil 2. Alternatively, the output of the output coil 2 may be directly connected to the power control unit to block the supply of power to the thermal line when a current flows in the output coil 2.

As described above, according to the present invention, there is an effect that the overheating of the electric bedding can be detected without increasing the thickness of the thermal wire.

In addition, according to the present invention, a thermal sensor having a temperature sensing function and an overheating or a short circuit may be used in an electric bedding device configured to block electromagnetic waves by allowing a current to flow in a direction opposite to each other in a heat wire, which is an inner layer of a heat ray, and a shielding lead wire, which is an outer layer. There is an effect that can be easily detected.

In addition, the bedding of general thermal wire type can solve 100% of the efficiency of the incoming power transformer and the noise in the hot wire by using only half a half cycle of the AC flowing through the heating wire to detect the overheat short circuit.

Claims (4)

(Once corrected) A sensing shield surrounding the heating wire 5 and the heating wire 5 and surrounding the thermal sensor unit 8 and the thermal sensor unit 8 in the form of a net, the resistance being lowered in proportion to temperature. A thermal wire made of a lead wire (6) and an insulating sheath (7) surrounding the sensing shield lead wire (6); A trans core 1 formed by joining two cores laterally; An end side current detection coil 3 wound around one core of the transcore and connected in series between the sensing shielded lead wire 6 and the heating wire 5 at one end of the heating wire; An input side current detection coil 4 wound around the other core of the transcore and connected in series between the heating wire 5 and an AC power supply at the other end of the heating core; And, And an output coil (2) wound around the coupling portion of the transcore, The end side current detection coil 3 and the input side current detection coil 4 are wound in a direction such that the magnetic flux at the coupling portion of the transcore is canceled when the current flowing in both current detection coils is the same. And the sensing shield lead wire (6) is grounded at the other end of the heat sensitive wire. delete (1 time correction) The method according to claim 1, The thermal sensor unit (8) is a nylon thermistor, the sensing shield lead wire (6) is a temperature detector using a magnetic field-free thermal wire, characterized in that configured in the form of a net. (1 time correction) The method according to claim 1, The output coil (2) is connected to the power control unit of the temperature controller, when the current flows in the output coil (2) characterized in that the power supply to the electric blanket is cut off, characterized in that the temperature using the non-magnetic thermal wire Detector.