KR101776784B1 - Automatic earth apparatus of controler for thermic mat - Google Patents

Abstract

A ground line is connected to a heating plate, an R terminal and an N terminal of a power line are normally connected to a central processing unit by controlling a relay, the rectified DC voltage of an alternate current, which is induced to a potential inducing line in a printed circuit board, is a primary lead, the R terminal and the N terminals intersect by re-controlling the relay, and the rectified DC voltage, induced to the potential inducing line, is a secondary lead to connect the power line of the controller with an N line, which is a grounded power line, in a connection mode of the R and N terminals, and thus, an electric field is not generated in the entire controller, so there is no need to connect a ground line with the rear side of the controller. Moreover, the present invention is capable of eliminating the need to coat the rear side with carbon powder, blocking a harmful magnetic field to a human body, solving inconvenience caused by an existing manual switchover method such as switching or relaying, and enabling automatic switchover by finally deciding the output of the central processing unit by selecting a lower value after comparison between input values of AC power of the central processing unit using a relay.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an automatic grounding apparatus for a heating bed controller,

The present invention relates to an automatic grounding apparatus for a controller for a heating bed requiring a temperature control such as a heating mat or a stone bed. More specifically, the present invention can block electromagnetic waves harmful to the human body, The present invention relates to an automatic grounding device for a controller for a heating bed, which can reduce manufacturing cost and prevent an economic loss by using a PTC heating wire.

As a known automatic grounding device for a controller for a heating bed widely known from the past, it is disclosed in Registration Practical Utility Model Registration No. 20-0445129 (Publication Date March 07, 2011).

The electric field automatic switching circuit for a temperature controller disclosed in the Registration Practical Utility Model Registration No. 20-0445129 includes a microcomputer for inputting two AC input power sources as a power source for the temperature controller and for controlling the overall operation of the circuit, The diode-side end of each of the two phototriacs is connected to the branched output end of each of the phototriacs, and the other end of each of the diodes is grounded, and the electric line shielding plate for the thermo- Circuit so that the potential of one AC input power source is applied to the input terminal of the triac side of the phototriac and the potential of the other AC input power source is applied to the input side of the triac side of the phototriac, On the triac side common output stage of the triac, capacitors, resistors and diodes are sequentially Connected in series to down-convert the input voltage of the AC to a low voltage, rectify the AC to DC current, and connect the signal to the microcomputer; A first oscillation unit having a connection structure of a resistor and a transistor and a second oscillation unit having a connection structure of a resistor and a transistor are connected between the branched output terminal of the microcomputer and the phototriac, The microcomputer reads the potential values of the two AC input power sources, compares the potential values, and oscillates and outputs an optional switching control with a smaller potential value.

However, since the electric automatic switching circuit for the temperature controller configured as above has a device called automatic EMI on the front side of the controller, when the power is inputted, the ground line is automatically detected and connected to the back plate of the nameplate Since the electric field is not completely blocked at the front part, carbon powder or the like must be coated on the nameplate, which is not only inconvenient but also has a problem of deteriorating the electric field effect.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an automatic grounding method in which a relay connected to a power input terminal is connected to an R terminal and an N terminal, Read the voltage and read the voltage by crossing the relay connected to the power input terminal of the secondary by the R terminal and the N terminal. If the voltage read out by the primary is more than the voltage read by the secondary, connect the relay connected to the power input terminal to the R terminal and the N terminal If the secondary reading voltage is lower than the primary reading voltage, if the relay connected to the power input terminal is crossed to the R terminal and the N terminal, the power supply line for the heating bed controller is connected to the grounded power supply line N (neutral line) It is possible to completely cut off the electric field because no electric field is generated in the entire power source connected to the line. Therefore, it is necessary to connect the ground line to the back of the nameplate of the controller. It is not as well to provide an automatic earthing device for heat bed controller without the need to coat the carbon powder on the name plate rear surface.

Another object of the present invention is to provide an automatic grounding apparatus for a controller for a heating bed, which can block a magnetic field harmful to a human body.

It is still another object of the present invention to provide an automatic grounding device for a controller for a heating bed, which can eliminate the inconvenience and inconvenience of a conventional switching type switching system such as a switch type or a relay type.

It is still another object of the present invention to provide an automatic grounding apparatus for a controller for a heating bed which can easily switch an electric field automatically.

Another object of the present invention is to use a relay to read an input power source from a central processing unit and a rectified voltage induced in a potential induction line from a central processing unit when the R terminal and the N terminal are normally connected, And an automatic grounding device for a controller for a heating bed, in which the processing unit can perform switching automatically by finally determining a relay output.

In order to achieve the above object, the automatic grounding apparatus of a controller for a heating bed according to the present invention comprises a first relay connected to an R terminal connected to EMI (Electro Magnetic Interference) And the DC power from the half-wave rectifier circuit is converted into DC to output DC 12V for the first relay and the second relay power and DC power for DC 5V for the operation power, respectively, after being lowered to 12V AC from the Mylar capacitor through the second relay A DC power supply unit; A central processing unit (also referred to as CPU) for receiving the direct current of 5V outputted from the direct current power source and controlling the entire operation; The central processing unit controls the first relay and the second relay to read the rectified DC voltage by normally connecting the R terminal and the N terminal and then connecting the R terminal and the N terminal to each other to cross the rectified DC voltage A potential-derived line through which a potential is induced to connect the R terminal and the N terminal to the lower voltage of the two voltages so as to shut off the electric field and the magnetic field; A rectifying unit that receives an AC output from the potential-guiding line, converts the AC into a direct current, and outputs the direct current to the central processing unit; When the central processing unit reads the voltage input from the rectifying unit and determines whether the R terminal and the N terminal should be normally or alternatively connected to each other to output a relay control signal so that the first relay and the second relay are operated A relay control unit for controlling the relay control unit; When 220V is applied to the R terminal and the N terminal, the control terminal d and the terminal e of the first relay and the control terminal i and the terminal j of the second relay are controlled by the relay control unit The contact "a" of the first relay is connected to the contact "b" and the contact "f" of the second relay "RY2" is connected to the contact "g" so that the AC voltage induced in the potential- And controls the control terminal d and the terminal e of the first relay and the control terminal i and the terminal j of the second relay in the relay control unit in accordance with the control of the central processing unit So that the contact "a" of the first relay is connected to the terminal "c" and the contact "f" of the second relay is connected to the contact "h" When the voltage is input to the central processing unit through the rectifying unit, the primary and secondary voltages of the rectifying unit are compared in the central processing unit, and the relay is controlled so that the voltage becomes low. A grounding resistor which is connected to an N-line which is a ground line whose line is grounded and the heating plate is automatically connected to the N-line; The central processing unit compares the preset temperature and the current temperature to output a trigger signal in the central processing unit if the current temperature is lower than a predetermined temperature, and compares the set temperature and the current temperature in advance to the central processing unit A triac control unit for interrupting the trigger signal in the central processing unit if the current temperature is higher than a preset temperature; A temperature check unit installed adjacently to an electric heating line disposed in the heat transfer plate to detect the temperature in the heat transfer plate by a thermistor and output the detected temperature to the central processing unit; And a control unit for controlling the central processing unit and the central processing unit so that the central processing unit and the central processing unit are connected in series to each other. When the current temperature is higher than a preset temperature, A triac which receives a control signal output from the central processing unit and interrupts an input / output signal of a power source applied to the heating line; A temperature display, a control panel for selectively flashing the first to fifth light emitting diodes, displaying a hot line state, and displaying time; .

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According to the automatic grounding apparatus for a controller for a heating bed according to the present invention, first, a ground line is connected to a heat conductive plate, and the central processing unit controls the first relay and the second relay to normally connect the R terminal and the N terminal of the power line The rectified DC voltage of the alternating current induced in the potential guide line inside the printed circuit board is firstly read and then the first relay and the second relay are controlled so that the R terminal and the N terminal of the power line are cross- The rectified DC voltage of the alternating current induced in the internal potential induction line is read secondarily and the rectified voltage is connected to the R terminal and the N terminal by the lower voltage so that the power supply line of the controller is connected to the grounded N line, Since the electric field is not generated, the electric field can be completely cut off, so that it is not necessary to connect the ground wire to the back surface of the nameplate of the controller It is not necessary to coat the carbon powder on the back surface of the plate, and secondly, the magnetic field which is harmful to the human body can be blocked. Thirdly, the troubles and inconveniences caused by the manual switching method, such as the conventional switch type or relay type, Fourthly, not only can the electric field be switched automatically and easily, but also the input value of the AC voltage is compared in the central processing unit using the relay, and the relay output of the central processing unit is selected It is possible to automatically perform the switching operation.

1 is a circuit block diagram schematically showing an automatic grounding apparatus of a controller for a heating bed according to an embodiment of the present invention.
2 is a plan view schematically showing a control panel part applied to an automatic grounding device of a controller for a heating bed according to an embodiment of the present invention.

Hereinafter, an automatic grounding apparatus for a controller for a heating bed according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the automatic grounding apparatus for a controller for a heating bed according to an embodiment of the present invention includes a relay (R) connected to EMI (Electro Magnetic Interference) and a relay RY1 and the second relay RY2 and is then converted into DC at the half-wave rectifying circuits D1 and D2 to be supplied to the first relay RY1 and the second relay RY2, A DC power source 20 for outputting DC 12 V for power supply for RY2 and DC power for DC 5 V for operation power; A central processing unit 10 (also referred to as a CPU) for receiving a direct current of 5 V outputted from the direct current power supply unit 20 and controlling the entire operation; The central processing unit 10 controls the first relay RY1 and the second relay RY2 to normally connect the R terminal and the N terminal to read the rectified DC voltage and then connect the R terminal and the N terminal The rectified DC voltage is read by crossing each other, and the R terminal and the N terminal are connected to the low voltage side of the two voltages, and the power supply line is connected to the DC power supply unit 20 so that the electric potential and magnetic field can be cut off A potential-guiding line (28); A rectifying unit 30 for receiving the AC output from the potential guiding line 28, converting the AC into DC, and outputting the DC to the central processing unit 10; A relay control unit 35 for controlling the first relay RY1 and the second relay RY2 according to the judgment of the central processing unit by the central processing unit 10 reading the voltage inputted from the rectifying unit 30; The control terminal d and the terminal e of the first relay RY1 and the terminal e of the first relay RY1 are controlled by the relay control unit 35 according to the control of the central processing unit 10 when AC 220 V is applied to the R terminal and the N terminal, The contact a of the first relay RY1 is connected to the contact b and the contact f of the second relay RY2 is connected to the contact g of the relay RY2 so that no current flows through the control terminal i and the terminal j of the relay RY2, The AC voltage derived from the potential lead line 28 is inputted to the central processing unit 10 through the rectifying part 30 and the relay control part 35 is controlled according to the control of the central processing unit 10. [ The control terminal d and the terminal e of the first relay and the control terminal i and the terminal j of the second relay RY2 are connected to the contact c of the first relay RY1, , The contact (f) of the second relay (RY2) is connected to the contact (h) When an AC voltage derived from the potential-guiding line 28 is input to the central processing unit 10 through the rectifying unit 30, the primary and secondary voltages of the rectifying unit 30 in the central processing unit 10 When the relay is controlled so as to be in a low voltage state by comparing the voltages, the relay plate is connected to an N-line, which is a power line grounded to the DC power supply unit 20, A resistor 38; The central processing unit 10 compares the preset temperature and the current temperature to output a trigger signal in the central processing unit 10 if the current temperature is lower than a preset temperature, A triac controller unit 40 for comparing the set temperature and the current temperature to shut off the trigger signal in the central processing unit 10 if the current temperature is higher than a preset temperature; A temperature check unit 50 provided adjacent to the heating line 52A disposed in the heating plate 51 and detecting the temperature in the heating plate 51 by the thermistor 53 and outputting the detected temperature to the central processing unit 10; The heating wires 52A and 52B are connected in series to compare the set temperature preset in the central processing unit 10 with the current temperature. If the current temperature is higher than a preset temperature, the cutoff signal of the bimetal 54 And outputs it to the central processing unit (10); A triac 70 which receives a control signal output from the central processing unit 10 and is applied to the heating wires 52A and 52B to interrupt the input and output signals of the power source; A temperature display, a control panel 80 for selectively flashing the first to fifth LEDs (LED1 to LED5), displaying a hot line state, and displaying time; .

When a control signal output from the central processing unit 10 is applied to the gate terminal G of the triac 70 through the triac controller unit 40, the magnetic field flowing through the heating wire 52A of the heat transfer plate 51 And the magnetic field flowing through the heating wire 52B of the heating plate 51 are canceled each other to become a non-magnetic heating wire.

The control panel 80 controls the application of power and includes a power button 81 for emitting a first light emitting diode (LED1) when the power is applied; A temperature decreasing button 82 for reducing the heating temperature by 1 degree Celsius each time the second light emitting diode LED2 emits light when the power button 81 is switched on; A temperature increase button 83 for increasing the heating temperature by 1 degree Celsius each time the third light emitting diode LED3 is lighted when the power button 81 is turned on; A reservation button 84 for indicating that the fourth light emitting diode LED4 is illuminated to indicate that reservation is being made when the power button 81 is switched on; A safety button 85 for indicating that the fifth light emitting diode LED5 emits light to indicate safety when the power button 81 is switched on; And display means 86 for indicating whether the power button 81, the temperature decreasing button 82, the temperature increasing button 83, the reservation button 84 and the safety button 85 are operated or not do.

Next, the operation of the automatic grounding device of the controller for a warm bed according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, the AC power source 20 receives AC 220V and converts the DC 12V and DC 5V into a DC 5V and outputs the DC 5V to the central processing unit 10 to determine whether AC 220V is normally input from the DC power source 20 And if the power of the central processing unit 10 is abnormal, receives the input power and stores the set temperature and the reserved time in the memory 10a installed in the central processing unit 10.

Each time the power button 81 of the control panel unit 80 is turned on and the temperature increase button 83 is pressed once, the heating temperature can be increased by 1 degree Celsius, The first and second light emitting diodes LED1 and LED3 emit light and the power button 81 and the temperature increase button 83 are turned on Display.

If the current temperature is lower than a preset temperature by comparing the set temperature preset in the memory 10a of the central processing unit 10 with the current temperature, the central processing unit 10 may control the triac control unit 40 The triac control unit 40 outputs a trigger signal to the gate terminal G of the triac 70 so as to output a trigger signal to the triac 70. When the trigger signal is outputted to the gate terminal G of the triac 70, And the heating wires 52A and the heating wires 52B of the heating plate 51 become non-magnetic heating wires, as the magnetic waves flowing in the heating wires 52B of the heating wires 51 are generated in opposite directions.

In other words, the magnetic wave flowing in the heating wire 52A of the heat transfer plate 51 is generated in a direction perpendicular to the heating wire 52A, and the magnetic fluxes flowing in the heating wire 52B of the heat transfer plate 51 are perpendicular to each other The magnetic field generated in the heating wire 52A of the heat transfer plate 51 and the magnetic flux generated in the heating wire 52B of the heat transfer plate 51 are offset from each other to form the heating wire 52A, (52B) is a non-magnetic insulation line free from generation of a magnetic field.

When the temperature of the heat transfer plate 51 exceeds a predetermined temperature, the temperature of the inside of the heat transfer plate 51 is lowered by the thermistor 53 disposed adjacent to the heating line 52A and the heating line 52B of the heat transfer plate 51, And is input to the central processing unit 10 and the memory 10a disposed in the central processing unit 10 through the temperature check unit 50 so that the display unit of the control panel unit 80 in the central processing unit 10 The temperature inside the heat transfer plate 51 is displayed on the display panel 86.

When the temperature of the heat transfer plate 51 exceeds a predetermined temperature, the bimetal 54 is connected in series to the heating line 52A and the heat transfer plate 52B of the heat transfer plate 51, The CPU 10 receives the input of the power off signal from the CPU 10 through the hot line checking unit 60 and outputs the signal to the central processing unit 10 and the memory 10a, Indicating that the bimetal 54 disposed in the heat transfer plate 51 is electrically turned off to the display means 86 of the display unit 80. [

When the reservation button 84 of the control panel unit 80 is depressed to reserve a time to return home after a certain period of time has elapsed, the fourth light emitting diode LED 4 emits light, and the central processing unit 10 The triac control unit 40 outputs a trigger signal to the gate terminal G of the triac 70 so as to conduct the heating wire 52A and the heating wire 52B to the set temperature, The fifth light emitting diode LED 5 emits light and is set at a preset temperature, for example, 30 degrees Celsius by the safety button 85. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, It goes without saying that the design changes as well as the design changes in various ways are included in the claims of the present invention.

10: central processing unit 10a: memory
20: DC power supply unit 28:
30: rectification part 35: relay control part
38: grounding resistance 40: triac control part
50: temperature check unit 51:
52A: heating wire 52B:
53: thermistor 54: bimetal
60: Heat line check unit 70: Triac
80: Control panel 81: Power button
82: Temperature decrease button 83: Temperature increase button
84: Reservation button 85: Safety button

Claims (2)

When AC 220V is applied to the R terminal and the N terminal connected to the EMI, the AC voltage is lowered to 12V from the Mylar capacitor C16 through the first relay RY1 and the second relay RY2. Then, the half-wave rectifying circuits D1, A direct current power supply unit 20 for converting direct current from the first relay RY1 and the second relay RY2 to direct current of 12 V for DC power and outputting DC power for direct current power of 5 V for the first relay RY1 and the second relay RY2;
A central processing unit (10) for receiving the direct current (5V) output from the direct current power supply unit (20) and controlling the entire operation;
The central processing unit 10 controls the first relay RY1 and the second relay RY2 to normally connect the R terminal and the N terminal to read the rectified DC voltage and then connect the R terminal and the N terminal The rectified DC voltage is read by crossing each other, and the R terminal and the N terminal are connected to the lower voltage of the two voltages, so that the grounded power supply line of the DC power supply unit 20 is connected to the N line, A potential-guiding line (28) through which a voltage is induced;
A rectifying unit 30 for receiving an AC output from the potential guiding line 28 and converting it into a DC current and outputting a DC voltage to the central processing unit 10;
A relay control unit 35 for controlling the first relay RY1 and the second relay RY2 according to the judgment of the central processing unit by the central processing unit 10 reading the voltage inputted from the rectifying unit 30;
The control terminal d and the terminal e of the first relay RY1 and the terminal e of the first relay RY1 are controlled by the relay control unit 35 according to the control of the central processing unit 10 when AC 220 V is applied to the R terminal and the N terminal, The contact a of the first relay RY1 is connected to the contact b and the contact f of the second relay RY2 is connected to the contact g of the relay RY2 so that no current flows through the control terminal i and the terminal j of the relay RY2, The AC voltage derived from the potential lead line 28 is inputted to the central processing unit 10 through the rectifying part 30 and the relay control part 35 is controlled according to the control of the central processing unit 10. [ The control terminal d and the terminal e of the first relay and the control terminal i and the terminal j of the second relay RY2 are connected to the contact c of the first relay RY1, , The contact (f) of the second relay (RY2) is connected to the contact (h) When an AC voltage derived from the potential-guiding line 28 is input to the central processing unit 10 through the rectifying unit 30, the primary and secondary voltages of the rectifying unit 30 in the central processing unit 10 When the relay is controlled so as to be in a low voltage state by comparing the voltages, the relay plate is connected to an N-line, which is a power line grounded to the DC power supply unit 20, A resistor 38;
The central processing unit 10 compares the preset temperature and the current temperature to output a trigger signal in the central processing unit 10 if the current temperature is lower than a preset temperature, A triac controller unit 40 for comparing the set temperature and the current temperature to shut off the trigger signal in the central processing unit 10 if the current temperature is higher than a preset temperature;
A temperature check unit 50 provided adjacent to the heating line 52A disposed in the heating plate 51 and detecting the temperature in the heating plate 51 by the thermistor 53 and outputting the detected temperature to the central processing unit 10;
The heating wires 52A and 52B are connected in series to compare the set temperature preset in the central processing unit 10 with the current temperature. If the current temperature is higher than a preset temperature, the cutoff signal of the bimetal 54 And outputs it to the central processing unit (10);
A triac 70 which receives a control signal output from the central processing unit 10 and is applied to the heating wires 52A and 52B to interrupt the input and output signals of the power source;
A temperature display, a control panel 80 for selectively flashing the first to fifth LEDs (LED1 to LED5), displaying a hot line state, and displaying time; And a controller for controlling the temperature of the heating bed. delete

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