KR200277313Y1 - Temperature regulator for detecting rated current of non-magnetic field heating wire in bedding - Google Patents

Abstract

The present invention relates to a thermostat for the rated current detection of bedding type magnetic heating wire, and other reasons when heating the shield heating heater or parallel two-wire heating heater used for the magnetic field (non-electromagnetic) used in bedding equipment When the low-shielded heating wire heater or parallel 2-wire heating wire heater is short-circuited at an arbitrary interval, an overcurrent flows, and a leakage current flows between the shield and the heating wire or between the parallel 2-wire heating wire, The purpose is to prevent overheating.

The temperature controller of the present invention includes: an AC current detection unit 6 for detecting a rated alternating current applied to heat the magnetic shield heating wire 3; A temperature detector 19 detecting the temperature of the shield heating wire through a temperature sensor; A power control unit 18 for controlling power applied to the shield heating wire by the temperature detection unit; A power supply unit 17 for supplying power to each circuit; A bridge rectifier 1 or 7 for converting an AC current into a DC current; In addition, the self-holding unit 6 receives the overcurrent detection signal from the AC current detecting unit and blocks and holds the power control unit.

Description

TEMPERATURE REGULATOR FOR DETECTING RATED CURRENT OF NON-MAGNETIC FIELD HEATING WIRE IN BEDDING}

The present invention relates to a thermostat for the rated current detection of bedding type magnetic heating wire, especially when heating a shield heating wire heater or a parallel two-wire heating heater used for the magnetic field (non-electromagnetic), which is used for electric bedding For other reasons, the shield heating wire heater or the parallel 2-wire heating wire is short-circuited at an arbitrary interval, causing an overcurrent to flow, a leakage current flowing between the shield and the heating wire, or a parallel 2-wire heating wire, or an overcurrent caused by fluctuations in the power supply voltage. The present invention relates to a rated current detection temperature controller of a bedding type magnetic field heating wire that can easily sense the current to block the heating wire heating power control unit and thereby prevent overheating.

Bedding equipment As a magnetic heating wire used, one end of the heating wire is supplied with electric power and the other end is shorted so that the electromagnetic is canceled to operate in a magnetic field. Such non-magnetic heating wire has a problem in that it cannot be detected conventionally when an increase in current and leakage current flow due to a short circuit due to a short circuit at an intermediate point due to other reasons. In other words, it does not detect the flow of more than the rated current. If such a phenomenon occurs, there is a high possibility of a fire accident due to overheating.

The present invention is made in consideration of the above-described conventional problems, when heating the shield heating wire heater or parallel two-wire heating wire heater used for the purpose of non-magnetic (non-electromagnetic), which is used for electric bedding, shield electric wire heater for other reasons Or when the parallel two-wire heating heater is shorted at any intermediate and an overcurrent flows, a leakage current flows between the shield and the heating wire or between the parallel two-wire heating wire, or when an overcurrent is generated due to fluctuations in the power supply voltage. It is intended to provide a rated current detection temperature controller of bedding type magnetic field heating wire that can be sensed so as to cut off the heating wire heating power control unit to prevent overheating.

1 is a circuit configuration diagram of a rated current detection temperature controller of a bedding type magnetic field heating wire according to the present invention, and shows a configuration of a method of detecting a load current detection by a resistance as a rated current.

FIG. 2 is a circuit diagram illustrating another example of a rated current detecting temperature controller of a bedding type magnetic field heating wire according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1, 7: bridge rectifier, 2, 11: condenser,

3: shield heating wire, 4: shield,

5: shield and heating wire connection point, 6: AC current detection unit,

8, 10, 12, 13: resistance, 9: phototransistor,

11: variable resistor, 15: voltage comparison amplifier,

16: self-retaining unit, 17: power supply unit,

18: power control unit, 19: temperature detection unit

In order to achieve the above object, the rated current detection temperature controller of the bedding type magnetic field heating wire according to the present invention, the AC current detection unit for detecting a rated alternating current applied to heat the magnetic shield heating wire; A temperature detector for detecting a temperature of the shield heating wire through a temperature sensor; A power control unit controlling power applied to the shield heating wire by the temperature detection unit; A power supply unit supplying power to each circuit; A bridge rectifier for converting AC current into DC current; And a self-holding unit which receives the overcurrent detection signal from the AC current detecting unit and blocks and holds the power control unit.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms or words used in the present specification and claims are defined in the technical spirit of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her own design. It must be interpreted to mean meanings and concepts.

1 is a circuit configuration diagram of a rated current detection temperature controller of a bedding type magnetic field heating wire according to the present invention, showing a configuration of a method of detecting the load current detection by the rated current by the resistance, and FIG. A circuit configuration diagram showing another example of the rated current detection temperature controller of the beddingless magnetic heating wire according to the present invention.

As shown, the rated current detection temperature controller of the bedding type magnetic field heating wire according to the present invention, the AC current detection unit 6, the temperature detection unit 19, the power control unit 18, the power supply unit 17, The bridge rectifier 1 and the magnetic retaining portion 16 are included.

The AC current detection unit 6 detects a rated AC current applied to heat the magnetic shield heating wire 3. The temperature detector 19 detects the temperature of the shield heating wire 3 through a temperature sensor when the shield heating wire 3 is heated. The power controller 18 controls the power applied to the shield heating wire 3 by the temperature detector 19. The power supply unit 17 supplies power to each circuit. The bridge rectifier 1 converts an AC current into a DC current. The magnetic holding unit 16 receives the overcurrent detection signal from the AC current detecting unit 6 by a flip-flop circuit, cuts and holds the power control unit 18.

In the present invention, the electromagnetic emission blocking principle by the alternating-current electronics converts the AC power applied to the shield 4 into direct current power so that electromagnetic stirring does not occur, thereby eliminating the energy release into the air, and in the shield 4 The DC electronics in Equation also ensure that the offset neutralization by phase difference does not occur.

Under the technical idea, when using the bedding with the rated current detecting thermostat of the beddingless magnetic heating wire of the present invention, the shielding heating wire (3) and the shield (4) or due to the overheating of the parallel two-wire heating wire heater When the intermediate point is shorted or a leakage current flows, the current detecting operation is performed as follows.

That is, DC power is applied to one end of the shield heating wire 3, and the other end is short-circuited between the shield heating wire 3 and the shield 4 or in parallel to the heating power supply line. Since the current detection resistor, that is, the AC current detection unit 6 is inserted, the current flowing in the shield heating wire 3 appears in proportion to the current detection resistance when the shield heating wire 3 is heated. This proportional signal voltage value is a current increase and shield due to a decrease in heating load resistance value due to overheating of the shield heating wire 3 and the shield 4 or the parallel two-wire heating heater, or other short-circuiting due to other reasons. Due to the overcurrent component generated by the overvoltage supply applied to the heating wire 3 and overheating or other reasons, the leakage current between the shield heating wire 3 and the shield 4 is increased and induced as it is. When the overcurrent signal voltage is compared with the signal voltage proportional to the rated current to trigger the magnetic holding unit 16, the power control unit 18 is controlled by the output signal from the magnetic holding unit 16. Therefore, the power applied to the shield 4 is cut off and maintained until the power is turned on again, thereby preventing overheating.

This will be described in more detail with reference to FIG. 1. Since the operation of the thermostat according to the present invention is known and used as a temperature control cycle generally used, the illustration of the electronic circuit is omitted and replaced with a configuration diagram.

First, when power is applied to the temperature controller circuit of the present invention through the power supply unit 17, the input side (+ side) potential of the voltage comparison amplifier 15 is reduced due to the resistance 13 of the capacitor 14 The initial charge time results in a high potential (HI). In addition, the input side (-side) of the voltage comparison amplifier 15 has no current flowing through the shield heating wire 3, so that the output transistor of the phototransistor 9 is turned off and the low potential LO is compared. Since the output of the amplifier 15 is maintained at the low level LO at the initial power supply, the operation of the self-holding unit 16 is automatically reset. The reset self holding unit 16 keeps the power control unit 18 in a normal operating state.

On the other hand, the power control unit 18 receives the signal of the temperature detector 19, and if the signal is less than the temperature set value, the power control unit 18 supplies the power AC voltage to the input side of the bridge rectifier 1, which is a DC converter. The current flowing through the bridge rectifier 1 is a light emitting diode of the phototransistor 9 through the load rated current detector resistance, that is, through the AC current detector 6, the bridge rectifier 7 (see FIG. 2) and the resistor 8. Since the output transistor of the phototransistor 9 is turned on and the load current value flowing through the bridge rectifier 1 and the shield heating line 3 appears in proportion to both ends of the variable resistor 11.

Heat heated in the shield heating wire 3 is transferred to the temperature sensor of the temperature detector 19. If the heating temperature value is higher than the temperature set value of the power control unit 18, the power control unit 18 stops the power supply to the bridge rectifier 1 to automatically maintain the temperature. Here, the structure of the shield heating wire (3) and the shield (4) is one end is a terminal for applying power, the other end is connected to the shield heating wire (3) and the shield (4) by interconnecting (connection point (5)) It is composed of structure that electromagnetic does not generate.

The AC current detection unit 6 is connected in series to the AC input power of the bridge rectifier 1 so that the bridge rectifier 1 and the load shield heat generating unit (ie, the heating wire 3, the shield 4, and the connection point 5) are connected. Induce the proportional current value flowing in proportion to the AC voltage signal. This AC signal potential is converted into direct current through the bridge rectifier 7 as shown in FIG. 2, and this signal is applied across the variable resistor 11 through the phototransistor 9. The potentials at both ends of the variable resistor 11 appear as they are in proportion to the rated current flowing through the bridge rectifier 1 and the load shield heat generating unit. The value of the rated current signal potential, that is, the potential output value of the variable resistor 11 is approximately 0.01, so that the output of the voltage comparison amplifier 15 does not become a high potential (HI) than the negative input potential of the voltage comparison amplifier 15. The potential output value across the variable resistor 11 keeping V low is the rated current signal potential value.

Here, due to the overcurrent other than the rated current flowing in the DC converter 1 and the load shield heating unit, the leakage current due to other reasons, the overcurrent proportional value due to the overheating short circuit of the heating wire 3 and the shield 4, and the increase of the power voltage. Due to the increase in current, the (+) input potential of the voltage comparison amplifier 15 is raised so that the output of the voltage comparison amplifier 15 becomes the low level (LO), and this signal drives the magnetic holding unit 16 to supply power. By stopping the operation of the control unit 18, the potential applied to the load shield heat generating unit is cut off.

This stop operation is maintained until the thermostat is turned off and the power is supplied again. This operation time is very fast, and it operates in advance before the power fuse is disconnected and performs the same safety operation as the power fuse disconnection. If the rated current value, that is, the resistance value of the heating wire 3, which maintains the surface temperature value of the heating wire 3 to a temperature at which it does not overheat, is maintained at the rated current value, the shield heating wire can be used safely in any state. .

As described above, in the rated current detection temperature controller of the bedding type magnetic field heating wire according to the present invention, while completely eliminating harmful electromagnetic waves generated by commercial electric alternating current electromagnetic waves of electric bedding materials used in direct contact with the human body, It can detect the overheat leakage current between the shield and heating wire by the heating wire or parallel 2-wire heating wire, the overcurrent by the short-circuit at any point of the heating wire due to the overheating, and the overcurrent due to the voltage fluctuation in a very short time. Thus, overheating of the heating wire can be prevented in advance. Therefore, it is possible to prevent the fire due to overheating, so the bedding can be used safely.

Claims (3)

An AC current detector for detecting a rated AC current applied to heat the magnetic shield heating wire; A temperature detector for detecting a temperature of the shield heating wire through a temperature sensor; A power control unit controlling power applied to the shield heating wire by the temperature detection unit; A power supply unit supplying power to each circuit; A bridge rectifier for converting AC current into DC current; And, And a self-holding unit which receives the overcurrent detection signal from the AC current detecting unit and blocks and holds the power control unit. The method of claim 1, And the rated current detecting temperature controller of the beddingless magnetic heating wire, characterized in that the shielded heating wire and the AC current detecting unit for inductively detecting the current supplied to the shield are converted into a current detecting transformer and detected as a rated load current signal. The method according to claim 1 or 2, A bedding apparatus comprising a phototransistor, resistors, a variable resistor, a capacitor, and a voltage comparison amplifier comprising a circuit for driving a flip-flop circuit of a magnetic holding section by receiving an input signal current value and comparing it with a rated current. Thermostat for detecting rated current of magnetic field-free heating wires.