KR101782795B1 - Temperature control system for electric heating mat or electric heating bedding including electric field automatic diverting function - Google Patents

Abstract

Disclosed is a heat transfer mat or heat transfer bed temperature control system having an electric field automatic switching function. A heat transfer mat or an electrothermal bonding bed temperature control system having an electric field automatic switching function includes a main body and a regulator, and the main body generates a power supply signal for controlling the supply of the commercial AC power to the hot wire based on the hot wire control signal And an electric field automatic control unit that receives the commercial AC power through the first and second AC power lines and adjusts the flow of the commercial AC power so as to automatically switch the electric field according to the potentials of the first and second AC power lines And the circuit of the electric field automatic control section includes a first bias resistor R1 and a first photocoupler PC1 connected in series to the first AC power supply line AC1 and a second bias resistor R2 connected to the second AC power supply line AC1, The node N1 between the first photocoupler PC1 and the second photocoupler PC2 is directly connected to the shielding plate and the second photocoupler PC2 is connected directly to the shielding plate. 1 capsule A coupling capacitor C1, a resistor R3 and a transistor Q1 are serially connected in series to a node N1 between the coupler PC1 and the second photocoupler PC2, R4 and the condenser EC1 to connect the shielding plate 10 and the space potential formed between the shielding plate 10 and the ground by connecting the integrating circuit 720 and the coupling resistor R5.

Description

TECHNICAL FIELD [0001] The present invention relates to a heating control mat for a heating mat or a heating mat for an electric heating bed,

The present invention relates to an electric heating mat having an electric field automatic switching function or a temperature control system for an electric heating bed and is provided with an electric field automatic switching function for controlling power supply of a heat ray used as a heating wire for an electric heating mat or a heating bed for electric heating bed And a temperature control system for a heat transfer mat or a heat transfer bed.

Electric heating mats and electric heating bedding are electric heating products that generate heat by using electric energy as a heat source. Examples of electric heating mats include electric mattresses, electric mattresses, and heat mattresses. Examples of electric mattress mattresses include stone beds. The electric heating product is equipped with a temperature controller for generating heat by supplying electric power to the built-in hot wire and controlling and controlling the temperature.

As the commercial AC power is supplied to the temperature regulator, an electric field and a magnetic field are formed. As a result, an electromagnetic wave is generated, which causes harm to the human body. In general, since the temperature controller is placed close to the human body for convenience of use by the user, a large amount of harmful electromagnetic waves are directly induced into the human body.

FIG. 8 is a circuit diagram showing an automatic grounding selector for preventing a potential and an electromagnetic wave generated in a conventional heat transfer mat from being induced in the human body. In this example, a line having a potential equal to that of a ground line among two lead- And an imaginary grounding point is formed on the circuit when there is no potential line such as grounding and is connected to the mat main body shielding plate so that potentials generated in the heat-transfer mat and electromagnetic waves are not induced in the human body. .

The conventional automatic grounding selector having the automatic switching switching circuit shown in FIG. 8 uses the fact that the input resistance of a port of a conventional microcomputer 12 composed of a MOSFET element is almost infinite, And a switching control for electromagnetic wave shielding is performed by detecting the space potential formed between the antenna and the ground by connecting an antenna (ANT) formed of a PCB pattern. In the case of using the PCB pattern antenna, (Space potential) of the electrostatic capacitance formed according to the distance between the temperature regulator and the floor changes, it is difficult to determine the accurate potential and the circuit operation becomes unstable.

As a result, it may cause a problem that it is very sensitive to a small change of the input voltage, and may also react sensitively to electrical noise around the antenna, thereby causing a malfunction.

The node N1 between the first photocoupler PC1 and the second photocoupler PC2 constituting the photocoupler portion 17 is connected to the shielding plate 14 and the circuit ground GND The electromagnetic wave shielding can be performed well under the cold electric potential state, but the electromagnetic wave shielding state is not generated well in the hot electric potential state, and the shielding is not performed well even in the case of the neutral shielding. .

In addition, Korean Patent Registration No. 10-1233252 (Feb. 23, 2013) for preventing the generation of electromagnetic waves discloses an electric field automatic switching circuit provided in a temperature controller capable of automatically switching an electric field without a shielding plate. Also, Korean Patent Registration No. 10-1659470 (Sep. 26, 2016) discloses a thermostat for a thermal bed comprising a copper foil coated with an insulator and a copper copper foil.

However, the conventional temperature controller has a problem that the generation of electromagnetic waves can not be prevented from the point of view that the commercial AC power flows inside.

SUMMARY OF THE INVENTION It is an object of the present invention to enable automatic switching of electromagnetic wave shielding through control of a control unit so that the spatial potential between the shield plate and the ground can be read and the input signal system input to the control unit can be accurately and stabilized The control unit determines the space potential and controls the switching output to the operating condition condition set in the control unit. Thus, it is possible to provide an accurate and stable potential detection and input, as well as an electric field And an object of the present invention is to provide a heat transfer mat having an automatic switching function or a temperature control system for a heat transfer bed.

Another object of the present invention is to provide an electrothermal mat or a temperature control system for electrothermal bonding bed having an electric field automatic switching function capable of preventing generation of an electric field and a magnetic field fundamentally in a heat transfer mat or a thermostat for a heat transfer bed have.

Another object of the present invention is to provide an electric heating mat or an electrothermal bonding bed temperature control system which is simple in installation of a body and a regulator and has an electric field automatic switching function that is easy to make and repair.

Another object of the present invention is to provide an electric heating mat or an electrothermal bedding temperature control system having an electric field automatic switching function in which a main body and a regulator can be separated from each other by a long distance and no separate power supply is required to the regulator There is.

In order to solve the above problems, an electrothermal mat or an electrothermal bonding bed temperature control system having an electric field automatic switching function according to the present invention is provided with a temperature control system for controlling power supply to a hot wire used as a heating wire of a heating mat or a heating bed The system comprising: a main body for receiving commercial AC power through first and second AC power lines and for converting a voltage of the commercial AC power source to a DC supply voltage; and a main body that is physically independent from the main body, The DC supply voltage is generated through the DC supply voltage, the operation voltage is generated, the operation voltage is generated without supplying the commercial AC power, and the function operation signal is received from the user , Generates the hot line control signal based on the function operation signal, and generates the hot line control signal based on the generated hot line control signal And a controller for controlling the supply of the commercial AC power to the hot wire on the basis of the hot wire control signal, And controls the flow of the commercial AC power so that the electric field is automatically switched according to the potentials of the first and second AC power lines Wherein the circuit of the electric field automatic regulating unit includes a first bias resistor (R1) and a first photocoupler (PC1) connected in series to the first alternating current power line and a second bias resistor The resistor R2 and the second photocoupler PC2 are connected in series and the node N1 between the first photocoupler PC1 and the second photocoupler PC2 is directly connected to the shield plate And a coupling capacitor C1, a resistor R3 and a transistor Q1 are connected in series to the node N1 between the first photocoupler PC1 and the second photocoupler PC2 directly connected to the shielding plate. And an integrating circuit 720 and a coupling resistor R5 are connected to the output terminal of the transistor Q1 by an RC parallel structure of a resistor R4 and a capacitor EC1 to connect the control unit to the shield plate and the ground And the control unit determines the space potential formed between the shield plate and the ground and outputs the space potential to the space between the first photocoupler PC1 and the second photocoupler PC2 in the pre- The switching elements of the first and second switching elements PC1 and PC2 are controlled to output 1 and output 2 so as to automatically switch the electric field. After the automatic switching, the electric field input is not accepted. To It can be controlled to the same. Here, the predetermined operation state may include at least one of a hot potential state, a cold potential state, and an intermediate potential state.

According to another aspect of the present invention, there is provided an electric heating mat or an electrothermal bonding bed temperature control system having an electric field automatic switching function according to the present invention, In the temperature control system for a mat or electrothermal bonding bed, a commercial AC power source is input through first and second AC power lines, and an electric field is automatically switched according to the potentials of the first and second AC power lines to prevent the generation of electromagnetic waves And a controller for controlling the flow of the commercial AC power supply, converting the voltage of the commercial AC power supply to a DC supply voltage, receiving a hot line control signal, Controlling the supply of the commercial AC power source to the hot line, controlling the supply of the hot line temperature signal indicating the temperature of the hot line, And a hot line check signal indicating information about an abnormality of the main body, and a main body which is physically independent from the main body and is connected to the main body in a wired manner, receives the direct current supply voltage via the main line, Extracting at least one of the hot line temperature signal and the hot line check signal from the received DC supply voltage, operating the generated operation voltage without supplying the commercial AC power, Displays a temperature associated with the hot-wire temperature indicated by the extracted hot-wire temperature signal, receives a function operation signal from a user, generates the hot-wire control signal based on the function operation signal, And a regulator for reducing the DC supply voltage and transmitting the heat ray control signal to the main body .

The main body includes an electric field automatic control unit that receives the commercial AC power through the first and second AC power lines and adjusts the flow of the commercial AC power so that the electric field is automatically switched according to the potentials of the first and second AC power lines. And a temperature sensor provided adjacent to the heat transfer plate on which the heat radiation line is disposed, wherein the system power supply unit converts the voltage of the commercial AC power supply to the DC supply voltage, A temperature check unit for detecting a temperature in the heat transfer plate and outputting the detected temperature to the control unit, a heat line check unit for detecting whether the thermal line is short-circuited and outputting the detected short circuit to the control unit, generating the hot line temperature signal based on the detected temperature, And generates the hot line check signal based on the output of the hot line control signal and at least one of the hot line control signal and the detected temperature And a control unit for controlling the supply of the commercial AC power to the hot wire in accordance with the power supply signal, and a controller for controlling at least one of the hot line temperature signal and the hot line check signal And a communication unit for transmitting at least one of the hot-wire temperature signal and the hot-wire check signal to the regulator, and extracting the hot-wire control signal from the direct-current supply voltage.

Wherein the communication unit further extracts a transmission start signal for confirming whether or not a signal is transmitted from the regulator at the DC supply voltage and outputs the transmission start signal to the control unit when the transmission start signal is extracted, It is possible to start checking the received control signal.

The controller receives the DC supply voltage through the wire, extracts at least one of the hot wire temperature signal and the hot wire check signal from the DC supply voltage, and controls the DC supply voltage based on the hot wire control signal A power source for generating the operating voltage by reducing the DC supply voltage, a display unit for displaying a temperature associated with a hot wire temperature indicated by the hot wire temperature signal, A user interface unit that receives an operation signal, and a controller that controls the set temperature based on the input function operation signal, generates the hot line control signal based on the function operation signal, and the hot line temperature indicated by the hot line temperature signal is And a control unit for controlling the display unit.

The communication unit includes a resistor R75 having one side connected to the wire and a collector terminal connected to the other side of the resistor R75 and receiving the hot wire control signal through a base terminal, A capacitor C26 connected to the wire to extract at least one of the hot-wire temperature signal and the hot-wire check signal, and an emitter connected to the earthing terminal, A base terminal is connected to the other terminal of the capacitor C26 and a pnp transistor Q18 connected to the output of the collector terminal for input to the control unit. can do.

According to the heat transfer mat or the temperature regulating system for electrothermal bonding bed having the electric field automatic switching function according to the present invention, the main body is supplied with the DC voltage of the lower voltage than the voltage of the commercial AC power source to the regulator, The electric field and the magnetic field which are harmful to the human body can be fundamentally cut off by inducing only the electric field and the magnetic field generation of an extremely small amount that does not generate electric field and magnetic field or is difficult to measure by originally supplied with the DC voltage of low voltage,

Since no additional power supply is required to the regulator by receiving power from the main body, and the transmission and reception signals are transmitted to the supply voltage, no additional wired installation for signal transmission other than the power supply is required, It is easy to install and easy to repair, and the body and the adjuster can be separated from each other by a long distance, so that the adjuster can be installed in a place where the user can easily use.

It is necessary to connect the shield plate to the node between the first photocoupler and the second photocoupler without using a method of connecting the shield plate to the circuit ground, and to set the spatial potential formed between the shield plate and the ground to the input potential, It is possible to detect accurate and stable electric potential and to induce input. In any case, it is possible to completely shield electromagnetic waves by automatic switching of electric field.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a preferred embodiment of a heat transfer mat or an electrothermal bonding bed temperature control system having an electric field automatic switching function according to the present invention.
2 is a block diagram showing the configuration of a preferred embodiment of the regulator according to the present invention.
3 is a block diagram showing a configuration of a preferred embodiment of the main body according to the present invention.
4 is a circuit diagram showing a configuration of a preferred embodiment of the communication unit and the power supply unit of the regulator according to the present invention.
5 is a circuit diagram showing a configuration of a preferred embodiment of the communication unit of the main body according to the present invention.
6 is a circuit diagram showing a configuration of a preferred embodiment of an electric field automatic control unit of a main body according to the present invention.
7 is a circuit diagram showing an electric field automatic switching circuit according to the present invention.
FIG. 8 is a circuit diagram showing an automatic ground selection controller having an automatic switching switching system according to the related art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a heat transfer mat or an electrothermal bonding temperature control system having an electric field automatic switching function according to the present invention will be described in detail with reference to the accompanying drawings. The structure and operation of the present invention shown in the drawings and described by the drawings are described as at least one embodiment, and the technical ideas and the core structure and operation of the present invention are not limited thereby.

Although the terms used in the present invention have been selected in consideration of the functions of the present invention, it is possible to use general terms that are currently widely used, but this may vary depending on the intention or custom of a person skilled in the art or the emergence of new technology. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Accordingly, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a preferred embodiment of a heat transfer mat or an electrothermal bonding bed temperature control system having an electric field automatic switching function according to the present invention.

1, an electric heating mat or an electrothermal bonding temperature control system 10 having an electric field automatic switching function according to the present invention includes a main body 100, a first regulator 20 and a second regulator 30 can do. The temperature control system 10 may include a main body 100 and a first regulator 20 and the main body 100 may include a first regulator 20 and a first regulator 20, And can be connected to the wired line 101. Here, the heat transfer mat may include an electric plate, an electric furnace, and a heat mattress, and the heat conductive bed may include a heat transfer bed and a stone bed.

The temperature regulating system 10 may include a main body 100, a first regulator 20 and a second regulator 30 and the main body 100 may include a first regulator 20 and a second regulator 30, The first regulator 30 and the second regulator 30 may be connected to the regulator 20 and the first wired line 102, respectively. In this case, the first regulator 20 may be referred to as a left regulator, and the second regulator 30 may be referred to as a right regulator.

The main body 100 receives the commercial AC power through the first AC power line AC1 and the second AC power line AC2 and receives the first AC power line AC1 and the second AC power line AC2 to prevent the generation of electromagnetic waves. The voltage of the commercial AC power supply can be switched to the DC supply voltage and the converted DC supply voltage can be supplied to the first regulator 20 or the second regulator 30). For example, the commercial AC power may be AC 110V or AC 220V. The DC supply voltage may be lower than the voltage of the commercial AC power supply, for example, the DC supply voltage may be DC 5V.

The main body 100 receives a heat ray control signal from the first regulator 20 and applies a commercial AC signal to the first heat ray H1 based on at least one of the received heat ray control signal and the temperature of the first heat ray H1. It is possible to generate at least one of a hot line temperature signal indicating the temperature of the first hot line H1 and a hot line check signal indicating the information on the abnormality of the first hot line H1 . Here, the first heating line H1 may be a heater heating line of the heating mat or the heating mat.

The main body 100 receives the heat ray control signal from the second regulator 30 and supplies the second heat ray H2 to a commercial alternating current (hereinafter referred to as " second heat ray ") based on at least one of the received heat ray control signal and the temperature of the second heat ray H2. It is possible to generate at least one of a hot line temperature signal indicating the temperature of the second hot line H2 and a hot line check signal indicating the information on the abnormality of the second hot line H2 . Here, the second heating line H2 may be a heating line of a heating mat or a heating mat of the heating bed.

The first regulator 20 is physically separate from the main body 100 and is connected to the main body 100 by a first wired line 101 and receives a DC supply voltage from the main body 100 through the first wired line 101 do. The first regulator 20 generates an operation voltage by stepping down the received DC supply voltage, and operates with the operation voltage generated without supplying the commercial AC power. Here, the operating voltage may be DC 3.3V, for example. The wire 102 may be for grounding.

The first controller 20 also extracts at least one of the hot line temperature signal and the hot line check signal transmitted by the main body 100 from the received DC supply voltage and displays the temperature associated with the hot line temperature indicated by the extracted hot line temperature signal .

The first regulator 20 receives a function operation signal from a user, generates a hot line control signal based on the function operation signal, downs the DC supply voltage based on the generated hot line control signal, (100).

The second regulator 30 is physically separate from the main body 100 and is connected to the main body 100 through a second wired line 103 and receives a DC supply voltage from the main body 100 through the second wired line 103 do. The second regulator 30 generates an operation voltage by stepping down the received DC supply voltage, and operates with the operation voltage generated without supplying the commercial AC power. Here, the operating voltage may be DC 3.3V, for example. The wire 104 may be for grounding.

The second controller 30 also extracts at least one of the hot line temperature signal and the hot line check signal transmitted by the main body 200 from the received DC supply voltage and displays the temperature associated with the hot line temperature indicated by the extracted hot line temperature signal .

The second controller 30 receives a function operation signal from a user, generates a hot line control signal based on the function operation signal, downs the DC supply voltage based on the generated hot line control signal, (100).

2 is a block diagram showing the configuration of a preferred embodiment of the regulator according to the present invention.

2, the controller 200 may include a communication unit 210, a power unit 220, a display unit 230, a user interface unit 240, and a controller 250. The regulator 200 can be the first regulator 20 shown in FIG. 1 and the second regulator 30.

The communication unit 210 receives the DC supply voltage from the main body 100 through the wire 201 and outputs the received DC supply voltage to the power supply unit 220. [ The wired line 201 may be the first wired line 101 or the second wired line 103 shown in Figure 1 and the wired line 202 may be the wired line 102 or the wired line 104 shown in Figure 1 . 2, the communication unit 210 is connected to the communication unit 180 of the main body 100 through two wired lines 201 and 202, and the wired line 202 may be a ground line.

The communication unit 210 can extract at least one of the hot line temperature signal and the hot line check signal transmitted by the main body 100 from the received DC supply voltage and output the extracted signal to the control unit 250. Here, the hot-wire temperature signal and the hot-wire check signal can be simultaneously transmitted, individually transmitted, and can be a pulse-width modulation (PWM) signal.

The communication unit 210 can downsize the DC supply voltage based on the hot wire control signal output from the controller 250 and transmit the hot wire control signal to the main body 100. [ Here, the hot wire control signal may be a pulse-width modulation (PWM) signal.

The power supply unit 220 can generate an operation voltage by reducing the DC supply voltage output from the communication unit 210. The communication unit 210, the power supply unit 220, the display unit 230, the user interface unit 240, and the control unit 250 are operated with the operation voltage. The operation voltage can be stably supplied to the regulator 200 even when the operation voltage is lower than the DC supply voltage and the signal is transmitted / received through the wired line 201. That is, even when the DC supply voltage is lowered by the hot wire control signal, the DC voltage supply voltage is kept higher than the operation voltage, so that the operation voltage can be stably supplied to the regulator 200. Also, even when the hot-wire temperature signal and the hot-wire check signal are loaded on the DC supply voltage, the DC supply voltage is maintained higher than the operation voltage, so that the operation voltage is stably supplied to the regulator 200.

The display unit 230 may display a temperature associated with the hot-wire temperature indicated by the hot-wire temperature signal under the control of the controller 250.

The user interface unit 240 can receive a function operation signal from a user and output the inputted function operation signal to the control unit 250. [ The user interface unit 240 may include a plurality of switches, and the user may input a function operation signal by pressing corresponding switches among the plurality of switches.

The control unit 250 controls the set temperature based on the function operation signal output by the user interface unit 240, generates the hot-wire control signal based on the function operation signal, and transmits the generated hot-wire control signal to the communication unit 210 ). The control unit 250 may control the heating control signal to be transmitted to the main body 100 when the main body 100 does not transmit a signal. Here, the controller 250 may be a microcontroller (MCU) or a microcomputer.

The control unit 250 receives the hot line temperature signal and the hot line check signal from the communication unit 210 and controls the display unit 230 to display the hot line temperature indicated by the received hot line temperature signal. When the hot line check signal indicates that the hot lines H1 and H2 are short-circuited, the control unit 250 can control the display unit 230 to display an abnormal signal and control the alarm to sound.

3 is a block diagram showing a configuration of a preferred embodiment of the main body according to the present invention.

3, the main body 100 includes an electric field automatic control unit 110, a system power unit 120, a heat line power unit 130, a temperature check unit 140, a heat line check unit 150, a control unit 160, A heating wire control unit 170, a communication unit 180, and a magnetic field system 190. FIG.

The electric field automatic regulating unit 110 receives the commercial AC power through the first AC power line AC1 and the second AC power line AC2 under the control of the controller 160 and receives the first alternating current The flow of the commercial AC power can be adjusted so that the electric field is automatically switched according to the potentials of the first line AC1 and the second AC power line AC2. When the plug is connected to the outlet, if the ground terminal of the outlet and the ground terminal of the alternating current line do not match, electromagnetic waves are generated. In the present invention, the controller 160 reads the voltage when the plug is connected to the outlet, and adjusts the two grounding terminals of the outlet to the normal grounding portions of the first and second AC power lines AC1 and AC2, respectively, It is possible to control the electric field automatic regulating unit 110 so as to be automatically connected to the electric field adjusting unit 110. [

The system power unit 120 can convert the voltage of the commercial AC power inputted through the first AC power line AC1 and the second AC power line AC2 to the DC power supply voltage. The electric field automatic regulating unit 110, the control unit 160, the heat ray control unit 170, and the communication unit 180 may be operated by the DC supply voltage.

The hot wire power supply unit 130 can supply the commercial AC power inputted through the first AC power line AC1 and the second AC power line AC2 to the hot wire H. [ Here, the hot wire H may be the first hot wire H1 or the second hot wire H2 shown in FIG.

The temperature check unit 140 may detect the temperature and output the detected temperature to the control unit 160. [ The temperature check unit 140 may detect the temperature in the heat transfer plate 340 through the temperature sensor 350 provided adjacent to the heat transfer plate 340 on which the heat transfer line H is disposed and output the detected temperature to the control unit 160. The temperature check unit 140 can detect the temperature of the hot wire H by confirming the change of the resistance of the hot wire H and output the detected temperature to the controller 160. [

The hot line check unit 150 may detect whether the hot line H is short-circuited and output the detected short circuit to the controller 160. A plurality of bimetals 360 are connected in series to the hot wire H so that when the temperature of the heat transfer plate 340 exceeds a preset temperature, the bimetal 360 is electrically turned off, The hot line check unit 150 can detect it and output it to the control unit 160. [

The control unit 160 may generate a hot-wire temperature signal based on the temperature detected by the temperature check unit 140, generate a hot-line check signal based on the output of the hot-line check unit 150, And can output a check signal to the communication unit 180. The controller 160 may control the heat ray temperature signal and the heat ray check signal to be transmitted to the regulator 200 when the regulator 200 does not transmit a signal. Here, the controller 250 may be a microcontroller (MCU) or a microcomputer.

The control unit 160 can receive the hot line control signal from the communication unit 180 and can generate the power supply signal based on at least one of the received hot line control signal and the detected temperature, And outputs it to the control unit 170.

The heat wire control unit 170 can control the supply of the commercial AC power to the hot wire H in accordance with the power supply signal outputted by the controller 160. [ The commercial AC power supplied through the hot-wire power supply unit 130 may be applied to the hot line H under the control of the hot-wire control unit 170.

The communication unit 180 downs the DC supply voltage supplied from the system power supply unit 120 based on at least one of the hot line temperature signal and the hot line check signal output from the controller 160 and outputs at least one of the hot line temperature signal and the hot line check signal To the controller 200.

The communication unit 180 can extract the hot line control signal transmitted from the regulator 200 at the DC supply voltage transmitted to the regulator 200 through the wired line 201 and output the extracted hot line control signal to the controller 160 .

The communication unit 180 detects a transmission start signal for confirming whether or not the signal of the regulator 200 is transmitted from the DC supply voltage to the regulator 200 through the wired line 201 and outputs the detected transmission start signal to the control unit 160 Can be output. The control unit 160 can start the operation of confirming the signal transmitted from the controller 200 when the transmission start signal is received from the communication unit 180. [

The magnetic field phase-change processing unit 190 may be formed in a PCB (Printed Circuit Board) pattern on the substrate to cancel the magnetic field flowing through the hot line H. The commercial AC power supplied under the control of the heat line control unit 170 may be applied to the hot line H through the magnetic field system 190. [

4 is a circuit diagram showing a configuration of a preferred embodiment of the communication unit and the power supply unit of the regulator according to the present invention.

4, the communication unit 210 may include a communication unit 410, and the power supply unit 220 may include a regulator 420. [

The regulator 420 is connected to the wire 201 and receives the DC supply voltage transmitted from the main body 100 through the wire 201 and downs the applied DC supply voltage to output the operation voltage VCC. Here, the operation voltage VCC may be DC 3.3V.

The communication section 410 includes an interface J14, a resistor R75, a transistor Q17, a resistor R74, a resistor R76, a capacitor C26, a transistor Q18, a resistor R40 and a resistor R73 . The wired line 201 can be fixed to the interface J14 and fixed and the regulator 420 can be connected to the wired line 201 through the interface J14.

One end of the resistor R75 may be connected to the wire 201 and the other end thereof may be connected to a collector terminal of the transistor Q17. The resistor R75 may be connected to the wire 201 via the interface J14.

The collector terminal of the transistor Q17 is connected to the resistor R75 and the hot wire control signal D_TX output from the control unit 250 is inputted through the base terminal and the emitter terminal It can be grounded or connected to a ground circuit. Here, the transistor Q17 may be an npn-type transistor.

One side of the resistor R74 may be connected to the emitter terminal of the transistor Q17, and the other side thereof may be grounded.

One side of the resistor R76 may be connected to the base terminal of the transistor Q17, and the other side thereof may be connected to the control unit 250. [ When the hot wire control signal D_TX is input to the transistor Q17 through the resistor R76, a current flows to the resistor R74 through the emitter terminal of the transistor Q17, The voltage is forced down and the hot wire control signal (D_TX) is put on the DC supply voltage.

The capacitor C26 is connected to the wire 201 and the other end is connected to the base terminal of the transistor Q18 so that the signal D_RX transmitted by the main body 100 from the DC supply voltage received through the wire 201, And output it to the transistor Q18. The signal D_RX may include at least one of a hot line temperature signal and a hot line check signal. The capacitor C26 may be connected to the wire 201 through the interface J14.

The transistor Q18 receives the operation voltage VCC output from the regulator 420 via the emitter terminal and the base terminal of the transistor Q18 is connected to the capacitor C26 to be connected to the capacitor C26, The signal D_RX may be applied and the collector terminal of the transistor Q18 may be connected such that its output is input to the control unit 250. [ Accordingly, when the signal D_RX is applied to the base terminal of the transistor Q18, a current having an amplified voltage higher than the operation voltage VCC flows to the collector terminal. That is, the signal D_RX is amplified through the transistor Q18 and output to the collector terminal. Here, the transistor Q18 may be a pnp-type transistor.

One side of the resistor R40 is connected to the collector terminal of the transistor Q18 and the other side of the resistor R40 is connected to the control unit 250. One side of the resistor R73 may be connected to the collector terminal of the transistor Q18, . The matching voltage is applied to the controller 250 according to the resistance values of the resistor R40 and the resistor R74. That is, the voltage of the collector terminal of the transistor Q18 is divided according to the resistance values of the resistors R40 and R74 and applied to the control unit 250. Accordingly, the control unit 250 outputs the signal D_RX).

5 is a circuit diagram showing a configuration of a preferred embodiment of the communication unit of the main body according to the present invention.

Referring to FIG. 5, the communication unit 180 may include a first heating communication unit 510, a second heating communication unit 520, and an initial signal detection unit 530. In some embodiments, the communication unit 180 may include a first heating communication unit 510 and an initial signal detection unit 530 when the heating mat or the heating bed is for a single occupant. In some embodiments, the communication unit 180 may include a first heating communication unit 510, a second heating communication unit 520, and an initial signal detection unit 530 when the heat transfer mat or the heat transfer bed is for two persons.

The first heating communication unit 510 transmits and receives signals to and from the first regulator 20 and transmits the DC supply voltage to the first regulator 20. [

The first heating communication unit 510 includes an interface J12, a resistor R65, a transistor Q16, a resistor R67, a resistor R68, a capacitor C24, a transistor Q10, a resistor R35, R66). The wired line 101 can be fixed to the interface J12 and fixed and the DC supply voltage VCC output from the system power supply unit 130 is supplied to the first regulator 20 via the wired line 101 via the resistor R65, Lt; / RTI >

The collector terminal of the transistor Q16 is connected to the resistor R65 and the wire 101 and the transmission signal M_TX1 output from the control unit 160 is input through the base terminal, emitter terminal can be grounded or connected to a ground circuit. Here, the transistor Q16 may be an npn type transistor, and the transmission signal M_TX1 may include at least one of a hot wire temperature signal and a hot wire check signal.

One side of the resistor R67 may be connected to the emitter terminal of the transistor Q16, and the other side may be grounded.

One side of the resistor R68 may be connected to the base terminal of the transistor Q16 and the other side thereof may be connected to the control unit 160. [ When the transmission signal M_TX1 is input to the transistor Q16 via the resistor R68, a current flows to the resistor R67 through the emitter terminal of the transistor Q16, And the transmission signal (M_TX1) is applied to the DC supply voltage.

The capacitor C24 is connected to the resistor R65 and the wire 101 and the other end is connected to the base terminal of the transistor Q10 so that the capacitor C24 is connected to the first regulator 20 at a DC supply voltage received through the wire 101, And outputs the extracted heat ray control signal M_RX1 to the transistor Q10.

The transistor Q10 receives the DC supply voltage VCC output from the system power supply 120 through the emitter terminal and the base terminal of the transistor Q10 is connected to the capacitor C22 to form the capacitor C24. And the collector terminal of the transistor Q10 may be connected such that the output of the collector terminal of the transistor Q10 is input to the control unit 160. [ Accordingly, when the hot wire control signal M_RX1 is applied to the base terminal of the transistor Q10, a current having a voltage higher than the DC supply voltage VCC flows to the collector terminal. That is, the hot wire control signal M_RX1 is amplified through the transistor Q10 and output to the collector terminal. Here, the transistor Q10 may be a pnp-type transistor.

One end of the resistor R35 is connected to the collector terminal of the transistor Q10 and the other end thereof is connected to the controller 160. The resistor R66 may be connected to the collector terminal of the transistor Q10 and the other end thereof may be grounded . And the matched voltage is applied to the controller 160 according to the resistance values of the resistor R35 and the resistor R66. That is, the voltage of the collector terminal of the transistor Q10 is divided according to the resistance values of the resistors R35 and R66 and applied to the control unit 160. Accordingly, the control unit 160 controls the heating line control Lt; RTI ID = 0.0 > M_RX1. ≪ / RTI >

The second heating communication unit 520 transmits and receives signals to and from the second regulator 30 and transmits the DC supply voltage to the second regulator 30. [ The second heating communication unit 520 includes an interface J13, a resistor R71, a transistor Q15, a resistor R70, a resistor R72, a capacitor C25, a transistor Q13, a resistor R36, R69). The wire 103 can be fixed to the interface J13 and fixed and the DC supply voltage VCC output from the system power supply 130 is transmitted to the second regulator 30 via the wire 103 via the resistor R71. Lt; / RTI >

The collector terminal of the transistor Q15 is connected to the resistor R71 and the wire 103 and the transmission signal M_TX2 output from the control unit 160 is input through the base terminal, emitter terminal can be grounded or connected to a ground circuit. Here, the transistor Q15 may be an npn type transistor and the transmission signal M_TX2 may include at least one of a hot wire temperature signal and a hot wire check signal.

One side of the resistor R70 may be connected to the emitter terminal of the transistor Q15, and the other side may be grounded.

One side of the resistor R72 may be connected to the base terminal of the transistor Q15 and the other side thereof may be connected to the control unit 160. [ When the transmission signal M_TX2 is input to the transistor Q15 through the resistor R72, a current flows to the resistor R70 through the emitter terminal of the transistor Q15, And the transmission signal (M_TX2) is applied to the DC supply voltage.

The capacitor C25 is connected at one end to the resistor R71 and the wire 103 and at the other end to the base terminal of the transistor Q13 so that the second regulator 30 is connected at the DC supply voltage received via the wire 103, And outputs the extracted hot wire control signal M_RX2 to the transistor Q13.

The transistor Q13 receives the DC supply voltage VCC output from the system power supply unit 120 through the emitter terminal and the base terminal of the transistor Q13 is connected to the capacitor C22 to form a capacitor C25. And the collector terminal of the transistor Q13 may be connected such that the output of the collector terminal of the transistor Q13 is input to the control unit 160. [ Accordingly, when the hot-wire control signal M_RX2 is applied to the base terminal of the transistor Q13, a current having an amplified voltage higher than the DC supply voltage VCC flows through the collector terminal. That is, the hot wire control signal M_RX2 is amplified through the transistor Q13 and output to the collector terminal. Here, the transistor Q13 may be a pnp-type transistor.

One end of the resistor R36 is connected to the collector terminal of the transistor Q13 and the other end thereof is connected to the controller 160. The resistor R69 may be connected at one end to the collector terminal of the transistor Q13, . The matched voltage is applied to the controller 160 according to the resistance value of the resistor R36 and the resistor R69. That is, the voltage of the collector terminal of the transistor Q13 is divided according to the resistance values of the resistors R36 and R69 and applied to the controller 160. Accordingly, the controller 160 controls the heating wire Lt; RTI ID = 0.0 > M_RX2. ≪ / RTI >

The initial signal detector 530 detects a transmission start signal RX_INT for confirming whether the first controller 20 or the second controller 30 transmits a signal and outputs the detected transmission start signal RX_INT to the controller 160 . The initial signal detecting unit 530 may include a diode D7, a diode D10, a resistor R37, a resistor R38, a transistor Q14, and a resistor R39. Here, the transistor Q14 may be a PNP type transistor.

The anode of the diode D7 is connected to the resistor R37 and the cathode is connected to the front end R35 of the first heating communication unit 510. [ The anode of the diode D10 is connected to the resistor R37 and the cathode is connected to the front end R36 of the second heating communication unit 520. [

One side of the resistor R37 is connected to the diode D7 and the diode D10 and the other side is connected to the base terminal of the resistor R38 and the transistor Q14.

One side of the resistor R38 is connected to the resistor R37 and the other side is connected to the emitter terminal of the transistor Q14.

The operation voltage VCC output from the system power supply unit 120 branches and is inputted to the emitter terminals of the resistors R38 and Q14 and the base terminal of the transistor Q14 is connected to the resistor 37 and the resistor And the output of the collector terminal of the transistor Q14 is connected to the controller 160 for input. When the hot wire control signal M_RX1 of the first regulator 20 or the hot wire control signal M_RX2 of the second regulator 30 is received, the current flows to the base terminal of the transistor Q14, The transfer start signal RX_INT can be input to the control unit 160 while the current having the same polarity is supplied to the collector terminal.

6 is a circuit diagram showing a configuration of a preferred embodiment of an electric field automatic control unit of a main body according to the present invention.

6, the electric field automatic regulating unit 110 includes a resistor R46, a resistor R47, a resistor R51, a resistor R52, a resistor R53, a resistor R54, a resistor R55, A first photocoupler U11, a second photocoupler U12, a capacitor 16, a capacitor C21, a capacitor C23, and a transistor Q8. One side of the resistor R54 is connected to the first AC power line AC1 and the other side is connected to the first photocoupler U11 and one side of the resistor R46 is connected to the second AC power line AC2, Is connected to the second photocoupler U11.

The control unit 160 controls the automatic electric field adjusting unit 110 to automatically perform the switching operation for the electromagnetic wave turn. The electric field automatic control unit 110 reads the spatial potential between the shield plate 610 and the ground. The control unit 160 determines the space potential and outputs the electric field control signals (Elec_H_out, Elec_L_out) according to the operating condition conditions set in the controller 160 to control the switching of the switching unit 610. The shield plate 610 is connected to the first photocoupler U11 and the second photocoupler U12 and performs switching for automatic switching of the electric field by using the spatial potential formed between the shield plate 610 and the ground as the input potential ELEC_A The signal is read to the transistor Q8 through the capacitor C23, the resistor R51 and the capacitor C21 and integrated into the integration circuit 111 by the RC parallel combination of the resistor R47 and the capacitor C16 to increase the sensitivity By providing the input signal Elec_Int to the control unit 160, the present invention can induce accurate and stable electric potential detection and input, and in any case, can completely shield the electromagnetic wave through the automatic switching of the electric field.

7 is a circuit diagram showing an electric field automatic switching circuit according to the present invention.

7, the electric field automatic regulating unit 110 includes an electric field automatic switching circuit for a temperature controller for controlling the temperature in an electric heating mat supplied with commercial AC power through the first and second AC power lines AC1 and AC2, (700).

The first bias resistor R1 and the first photocoupler PC1 are connected in series to the first AC power supply line AC1 to which the commercial AC power is applied and the second AC power supply line AC2 is connected in series, The second bias resistor R2 and the second photocoupler PC2 are connected in series.

The node N1 between the first photocoupler PC1 and the second photocoupler PC2 is directly connected to the shielding plate 710. [

A coupling capacitor C1, a resistor R3 and a transistor Q1 are sequentially connected to a node N1 between a first photocoupler PC1 and a second photocoupler PC2 directly connected to the shielding plate 710 And an integrating circuit 720 and a coupling resistor R5 in the RC parallel structure of the resistor R4 and the capacitor EC1 are connected to the output terminal of the transistor Q1 in the series connection, 710) and the ground.

At this time, the coupling capacitor C1 acts to pass only the signal of the AC component corresponding to the detection information of the spatial potential formed between the shielding plate 710 and the ground, and the transistor Q1 serves as an AC The integrating circuit 720 using the capacitor EC1 and the resistor R4 integrates the amplified signal of the spatial potential to enhance stable signal processing and sensitivity To the control unit 160 side.

The output terminal of the controller 160 is divided into an output 1 and an output 2 and is connected to control the respective switching elements of the first photocoupler PC1 and the second photocoupler PC2.

At this time, the controller 160 receives the input signal of the spatial potential formed between the shield plate 710 and the ground, converts the analog value of the input spatial potential into a digital value, reads the digital value, And controls ON / OFF of the switching elements of the first photocoupler PC1 and the second photocoupler PC2 by controlling the output 1 and the output 2 under the preset operating condition condition in the controller 160 .

The control unit 160 processes the space potential of the shielding plate 710 to detect the space potential of the shielding plate 710 only at the initial stage when the power is applied through the first and second AC power lines AC1 and AC2, (Electromagnetic wave shielding) according to the present invention, it is configured so as not to accept the electric field input of the space potential any more, and a reference value for judging the hot potential state, the cold potential state and the intermediate state with respect to the inputted space potential is set And controls ON / OFF of the first photocoupler PC1 and the second photocoupler PC2 according to whether the hot potential state, the cold potential state, or the intermediate state is determined, thereby automatically switching the electric field.

In addition, the control unit 160 stops the operation of the hot wire of the heat transfer mat before the automatic switching of the electric field, and operates the hot wire when the automatic switching is completed, so that the electric field automatic switching can be performed stably and completely.

Here, the shielding plate 710 will be used in a generic sense including all kinds of shielding members, that is, including the shape of the shielding line or other shielding means other than the shape of the plate.

The operation of the electric field automatic switching circuit 700 having such a configuration will be described below.

When the power plug of the temperature controller connected to the heat-transfer mat having the hot wire is inserted into the electric socket, the AC input power is applied to the temperature controller through the first and second AC power lines AC1 and AC2. At this time, in any one of AC power supply lines AC1 and AC2, AC 220 (hot potential) is formed, AC 0V (cold potential) is formed, or AC 110V (intermediate potential) Hereinafter, the first alternating current line AC1 will be described.

In each of the above cases, the controller 160 turns off the initial first photocoupler PC1 and the second photocoupler PC2 to be in a state in which there is no operation signal, and the shield plate 710 and the ground The spatial potential formed on the substrate is read.

The space potential between the shield plate 710 and the ground formed in a state in which the operation signals of the first photocoupler PC1 and the second photocoupler PC2 are absent is generated by coupling capacitors C1 and R3, And the transistor Q1 and is integrated through the integration circuit of the resistor R4 and the capacitor EC1 by the RC parallel arrangement and then inputted to the control unit 160 via the coupling resistor R5, It is possible to stably and accurately signal and transmit the input potential value of the detected spatial potential through the sensor, as well as to increase the sensitivity.

Here, before the AC input power source is applied to the temperature controller, that is, before the electric field is automatically switched, the control unit 160 stops the operation of the hot wire of the heat transfer mat so that the stable detection of the space potential formed between the shield plate 710 and the earth Allow input to be performed.

The control unit 160 converts the analog value of the spatial potential formed between the shielding plate 710 and the ground to a digital value and reads the analog value. The control unit 160 compares and determines the input potential value of the sensed spatial potential with the preset reference value, 710 by controlling the operation of the first photocoupler PC1 and the second photocoupler PC2 through the output 1 and the output 2 according to the sensing state of the space potential formed around the shielding plate 710, So as to absorb the electric field generated from the hot line of the heat transfer mat to shield the electromagnetic wave.

At this time, the control unit 160 reads the space potential formed between the shield plate 710 and the ground, and as a result, if it is in the hot potential state, the controller 160 turns on the second photocoupler PC2 through the output 2, The shielding plate 710 is connected to the first AC power line AC1 via the second photocoupler PC2 and absorbs the electric field generated from the hot line of the heat transfer mat.

The control unit 160 turns on the first photocoupler PC1 through the output 1 so that the shield plate 710 is connected to the second alternating current line AC2 through the first photocoupler PC1, And absorbs the electric field generated from the hot line of the heat transfer mat.

The controller 160 turns on both the first photocoupler PC1 and the second photocoupler PC2 via the output 1 and the output 2 so that the shield plate 710 is electrically connected to the first photocoupler PC1, Is connected to the second AC power line AC2 through the first photocoupler PC1 and connected to the first AC power line AC1 through the second photocoupler PC2 to absorb the electric field generated from the heating line of the heating mat at the virtual neutral point.

After the automatic switching is performed according to the application of the AC input power, the control unit 160 maintains the automatic switching state and does not accept any electric field input of the space potential. When the automatic switching is completed, To operate normally.

Therefore, the electric field automatic switching circuit for the temperature controller of the present invention does not use the method of connecting the shielding plate 710 to the circuit ground, but the node N1 between the first photocoupler PC1 and the second photocoupler PC2 And the transistor Q1 is connected through the coupling capacitor C1 and the resistor R3 to switch the electric field for automatic switching by setting the space potential formed between the shield plate 710 and the earth as the input potential, And integrated into the integrating circuit 720 by the RC parallel combination of the resistor R4 and the condenser EC1 to increase the sensitivity and provide the input signal to the control unit 160 side so that the electromagnetic wave can be completely shielded in any case .

The present invention can also be embodied as computer-readable codes on a computer-readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and may be implemented in the form of a carrier wave (for example, transmission via the Internet) . The computer-readable recording medium may also be distributed over a networked computer system so that computer readable code can be stored and executed in a distributed manner.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

Temperature control system 10 Body 100
First regulator 20 Second regulator 30

Claims (2)

A heating control system for controlling power supply to a heating wire used as a heater heating wire of an electric heating mat or a heating bed,
A main body for receiving a commercial AC power source through the first and second AC power lines and converting the voltage of the commercial AC power source to a DC supply voltage; And
And a control unit connected to the main body to receive the direct current supply voltage through the wire, to generate an operation voltage by stepping down the direct current supply voltage, And a control unit for receiving the function operation signal from the user, generating a hot line control signal based on the function operation signal, changing the DC supply voltage based on the generated hot line control signal, And a controller for transmitting to the body,
The main body includes:
A control unit for generating a power supply signal for controlling the supply of the commercial AC power to the hot wire based on the hot wire control signal; And
And an electric field automatic control unit that receives the commercial AC power through the first and second AC power lines and adjusts the flow of the commercial AC power so that the electric field is automatically switched according to the potentials of the first and second AC power lines ,
Wherein the circuit of the electric field automatic control unit comprises:
A first bias resistor R1 and a first photocoupler PC1 are connected in series to the first AC power supply line and a second bias resistor R2 and a second photocoupler PC2 are connected in series to the second AC power supply line The node N1 between the first photocoupler PC1 and the second photocoupler PC2 is directly connected to the shield plate;
A coupling capacitor C1, a resistor R3 and a transistor Q1 are connected in series to a node N1 between a first photocoupler PC1 and a second photocoupler PC2 directly connected to the shielding plate An integrating circuit 720 and a coupling resistor R5 formed by an RC parallel structure of a resistor R4 and a capacitor EC1 are connected to the output terminal of the transistor Q1 so that the control unit is formed between the shield plate and the ground And a spatial potential to be input is inputted,
Wherein,
The switching device of the first photocoupler PC1 and the switching device of the second photocoupler PC2 are switched to the output 1 and the output 2 in accordance with the operating conditions of the preset operating condition by judging the space potential formed between the shielding plate and the ground Wherein the control unit controls the control unit so as to automatically switch the electric field so that the electric field input is not received after the automatic switching, The temperature control system comprising: The method according to claim 1,
The pre-set operating state may include:
A hot potential state, a cold potential state, and an intermediate potential state.

Images