KR20130058860A - Circuit for protecting electromagnetic wave radiation - Google Patents

Abstract

PURPOSE: An automatic EMI shielding circuit built in a temperature controller is provided to simplify a structure by connecting two photo TRIACs and one MICOM, thereby improving the user convenience. CONSTITUTION: A MICOM outputs a low signal to a corresponding pin. An inner LED is operated by resistances(R1,R4). AC input power(AC1,AC2) is inputted through resistances(R3,R6). The inputted AC input power is outputted through resistances(R2,R5). The MICOM stops the operation of a photo TRIAC. [Reference numerals] (AA) Antenna-reception; (BB) Antenna-origination

Description

CIRCUIT FOR PROTECTING ELECTROMAGNETIC WAVE RADIATION}

The present invention relates to an automatic electromagnetic shielding circuit built in a temperature controller, and more particularly, the AC input power (AC1) (AC2) is connected to a neutral point to shield electromagnetic waves even when the AC power cord is inverted into an outlet. It is to provide an automatic electromagnetic shielding circuit built in a thermostat.

In general, electric products such as thermal mats or stone beds that generate heat by using electrical energy as a heat source generate electric and magnetic fields as electric current is supplied, and harmful electromagnetic waves are formed by the electric fields to harm the human body.

In particular, in the case of the thermal mat, since the built-in heating wire and the human body are close to each other, there is a problem that an electric field and a large amount of harmful electromagnetic waves are directly induced to the human body.

In order to solve the above problems, technology using materials such as ocher, jade, elvan, and charcoal may be combined, but the effect is less than expected, and shielding material may be used to surround the heating wire, the upper or lower heating wire, or the heating wire. If the shielding material is not shielded through the ground wire, electromagnetic waves penetrate the shielding material and cause many harmful effects on the human body.

In addition, AC power is supplied through two terminals (or wires), one of which becomes a terminal (wire) having the same potential as the ground wire and the other becomes a terminal (wire) of the positive (-) potential. When the same potential is connected to the ground line according to the insertion direction of the power plug provided in the thermostat, it is possible to generate electromagnetic waves below a certain value or to shield the electromagnetic waves. Will be generated.

For this reason, the conventional temperature controller is equipped with a probe terminal which can be touched by a finger, and when a harmful electromagnetic wave is generated, the technology for turning on and displaying an LED lamp is applied. Manual switching is used to shield the circuit.

In addition, when the lamp is turned on and the generation of harmful electromagnetic waves is confirmed, it is also possible to apply the method of connecting the power plug of the thermostat in the opposite direction again.

However, in the prior art, the manual switching switching method for shielding electromagnetic waves has a procedure of checking each time that harmful electromagnetic waves are generated through the probe terminal whenever the power plug of the thermostat for use of the thermal mat is connected to the power outlet. In order to shield this and necessary, the user has to perform an operation for switching switching every time there is a troublesome and inconvenient problem.

In addition, the conventional manual switching switching method has a problem that the contact portion is damaged and noise is generated when switching the ON / OFF switch due to the switch or relay mechanical contact structure is applied, there is a problem that can not be used for a long time.

Republic of Korea Utility Model Registration Publication No. 20-0445129

The present invention is proposed to solve the above problems,

An object of the present invention is to eliminate the inconvenience and inconvenience in accordance with the manual switching switching method, such as the conventional switch type or relay type, and a temperature controller to automatically execute the switching switching for electromagnetic shielding through the microcomputer control Its purpose is to provide an automatic electromagnetic shielding circuit built in.

In addition, it has a contactless structure by the phototriac, and the electromagnetic shield is built in the temperature controller which automatically switches the switching by comparing the input value of the AC power in the microcomputer and selecting the smaller value to determine the microcomputer output. The purpose is to provide a circuit.

The present invention includes the following embodiments in order to achieve the above object.

According to the present invention, when the AC input power source AC1 is applied, the phototrial liquid # 1 and the phototrial liquid # 2 are in an inoperative state, and then the microcomputer is operated to operate the phototrial liquids # 1 and # 2. If (Micom) outputs "LOW SIGNAL" to the corresponding pin, the internal LED of the phototriac (# 1) is operated by the resistors R1 and R4 so that the AC input power inputted through the resistors R3 and R6 AC2) is output through resistors R2 and R5, connected via capacitor C1 to an electric mat, and flows through capacitor C2 to ground. The inputted electromagnetic wave enters the base terminal of TR1 and is amplified to a voltage level that can be recognized by Micom by resistor R7 and capacitor C3, and then inputs to Micom. Measure the input ADC value by using and store it in variables 1, 2 and then Is small is characterized in that to stop.

When the voltage input to the AC input power supply is a short voltage, the measured values of the variable 1 and the variable 2 in the micom are compared with each other to operate the phototriac corresponding to the lower one of the measured variable values. It is characterized in that the neutral of the AC input power (AC1) (AC2) is connected to shield the electromagnetic waves.

If the voltage input to the AC input power is a positive voltage, the measured values of the variables 1 and 2 in the microcomputer are almost the same. The power source AC1 is a resistor R2, and the AC input power source AC2 is a resistor R5, and an AC input power source AC made of a neutral point is output and connected to the capacitor C1 to shield electromagnetic waves. It is done.

As described above, the automatic electromagnetic shielding circuit built in the temperature controller of the present invention has a simple configuration in which two phototriacs and one microcomputer are connected, and can automatically perform switching switching for electromagnetic shielding, and the power plug of the temperature controller Regardless of the direction of insertion, the shielding can be performed stably.Even when using the temperature controller as before, the user directly checks the occurrence of electromagnetic waves every time and also eliminates the inconvenience and inconvenience of switching switching manually. It may thus provide ease of use and stability.

In addition, since the phototriac having a non-contact structure is used, there is no damage to the contact even during long-term use and noise is not generated during switching, thereby enabling a stable circuit configuration.

1 is an exemplary view showing a configuration of an automatic electromagnetic shielding circuit built in the thermostat of the present invention.
2 to 3 are diagrams of an oscilloscope waveform in a short voltage state according to the present invention.
4 is a diagram of an oscilloscope waveform in a positive voltage state according to the present invention;

The present invention will now be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the automatic electromagnetic shielding circuit built in the temperature controller according to the present invention has two AC input power sources AC1 and AC2 as input power for use of the temperature controller and a microcomputer for overall operation control of the circuit. Micom is provided.

The output terminal of the microcomputer Micom is branched, and one of the branch lines causes the output signal of the microcomputer Micom to be applied to one phototriac # 1. It is applied to the triac side input terminal of the liquid PC1 and the triac side output terminal is connected to be input to the Micom side.

At this time, the one or the other side of the phototrial liquid (# 1) (# 2) forms a common output terminal and a common ground terminal, and the capacitor (C1) to the common output terminal of the phototrial liquid (# 1) (# 2) It can be connected to the deployment mat, and to be connected to the ground through the condenser (C2), but when the electromagnetic wave comes out through the antenna-emission, the electromagnetic wave is input through the antenna-receiving and enters the base end of TR1 and the resistor (R7) And amplified to voltage level recognizable by Micom by condenser C3 and input to Micom, measure the input ADC value using Micom's ADC function By stopping the operation of the phototriac # 1 (# 2) after storage, the microcomputer Micom is configured to oscillate output selective switching control to the phototriac # 1 (# 2) side.

Referring to the operation and operation of the automatic electromagnetic shielding circuit built in the thermostat of the present invention having such a configuration as follows.

When the power plug of the thermostat connected to the thermal mat is inserted into the electrical outlet, two AC input powers are applied to the temperature controller. As shown in the circuit of FIG. 1, one AC input power AC1 is connected to one side of the phototri It is explained that it is applied to the liquid # 1 and another AC input power source AC2 is applied to the other phototrial liquid # 2.

First, when the AC input power source AC1 is applied, the initial phototrial solution # 1 and the phototrial solution # 2 remain in an inoperative state, and then at Micom to operate the phototrial solution # 1. When outputting "LOW SIGNAL" to the corresponding pin, the internal LED of the phototriac (# 1) is operated by the resistor R1 so that the AC input power AC1 input through the resistor R3 passes through the resistor R2. It is output and is connected to the electric mat through the capacitor (C1) and flows to the ground through the capacitor (C2). When the electromagnetic wave comes out through the antenna-outgoing, the electromagnetic wave input through the antenna-receiving enters the base end of TR1. When R7 and capacitor C3 are amplified to voltage level recognizable by Micom and input to Micom, the input ADC value is measured by using Micom's ADC function. After saving to Phototriac (# 1) stop the operation For decades the chattering of Jaffa ms ~ waits with hundreds of ms.

To operate the phototriac (# 2) again, if Micom outputs "LOW SIGNAL" on the corresponding pin, the internal LED of the phototriac (# 2) is operated by the resistor (R4), which causes the resistor (R6). AC input power AC2 inputted through R2 is output through resistor R5 and flows to ground via capacitor C2. When the electromagnetic wave comes out through antenna-outgoing, the electromagnetic wave input through antenna-receiving is TR1. Enter the base stage of the resistor (R7) and capacitor (C3) by a voltage level that can be recognized by Micom (Micom) is input to Micom (Micom) when the ADC input using the Micom ADC function Measure the value and store it in Variable 2.

By comparing the measured values with respect to the variables 1 and 2 in the Micom using the circuit as described above,

First, when the AC input power (AC) is composed of 220V and 0V with most of the corresponding voltages in Korea, as shown in FIG. 2, the AC input power (AC1) is connected to 220V and the AC input power (AC2) When connected to 0V or connected to AC input power AC1 as 0V and connected to AC input power AC2 as 220V, the phototriac corresponding to the lower one of the measured variable values is operated. Neutrality of the AC input power source AC1 or AC2 is connected to shield electromagnetic waves.

On the other hand, when the AC input power (AC) is composed of 110V, 110V with a positive voltage, as shown in Figure 4, the measured value for the variable 1, variable 2 in the Micom (Micom) is almost the same, the phototri When both liquids # 1 and # 2 are operated, AC input power AC1 is a resistor R2, AC input power AC2 is a resistor R5, and an AC input power AC made of a neutral point is output. Electromagnetic waves are shielded by connecting to the capacitor (C1).

Accordingly, a simple circuit configuration including two phototriacs (# 1) (# 2) and one microcomputer (Micom) automatically switches switching for electromagnetic shielding regardless of the insertion direction of the power plug of the temperature controller. As it is, it is possible to eliminate the inconvenience and inconvenience of having to check the occurrence of electromagnetic waves every time and manually switch switching as before.

In addition, since the present invention uses the phototriac (# 1) (# 2) having a non-contact structure, there is no damage to the contact even during long-term use and noise is not generated during switching, thereby providing the usefulness of constructing a stable circuit.

Claims (3)

When the AC input power source AC1 is applied, the phototrial liquid # 1 and the phototrial liquid # 2 are in an inoperative state, and then the microcomputer (Micom) is operated to operate the phototrial liquids # 1 and # 2. Outputs "LOW SIGNAL" to the corresponding pin at, the internal LED of the phototriac (# 1) is operated by the resistors R1 and R4, and the AC input power (AC1, AC2) input through the resistors R3 and R6 It is output through the resistors R2 and R5, connected to the electric mat through the capacitor C1, and flows to the ground through the capacitor C2. When electromagnetic waves enter the base of TR1 and are amplified to a voltage level recognizable by Micom by resistor R7 and capacitor C3 and input to Micom, Micom ADC function is used. Measure the input ADC value and store it in variable 1, 2 and then operate the phototriac (# 1, # 2). The automatic built-in electromagnetic wave shield circuit to the thermostat, characterized in that The method of claim 1,
When the voltage input to the AC input power supply is a short voltage, the measured values of the variable 1 and the variable 2 in the micom are compared with each other to operate the phototriac corresponding to the lower one of the measured variable values. Automatic electromagnetic shielding circuit built in the temperature controller characterized in that the neutral of the AC input power (AC1) (AC2) is connected to shield the electromagnetic waves The method of claim 1,
If the voltage input to the AC input power is a positive voltage, the measured values of the variables 1 and 2 in the microcomputer are almost the same. The power source AC1 is a resistor R2, and the AC input power source AC2 is a resistor R5, and an AC input power source AC made of a neutral point is output and connected to the capacitor C1 to shield electromagnetic waves. Automatic electromagnetic shielding circuit built in thermostat

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