KR200275207Y1 - A none electromagnetic wave heat controler for an electric heating bedding - Google Patents

Abstract

The present invention relates to a non-electromagnetic temperature controller for a heater used to be connected to the heater body as a connector for temperature control of the heater, and more particularly, it is possible to remove electromagnetic waves from the heater body without changing the structure of the heater body. The circuit is designed to make the temperature control circuit using the integrated circuit NE555, the frequency oscillator with switching and timing functions, harmless to the human body. Functions and functions of power saving, and by configuring the above circuit inside the temperature controller, if only the thermostat of the present invention is connected and connected without the improvement of the body of the heater, conventional electric heaters, such as electric blankets also remove the electromagnetic wave and the effect of power saving Non-electromagnetic thermostat for heater It's about the season.

According to the present invention, the AC power is connected to the temperature controller, the current output from the temperature controller is supplied to the heater body through the connection port, the circuit including the NE555 is configured, the light emitting diode and the resistor in series at the output terminal of the NE555 A non-electromagnetic thermostat for the heater is provided, connected to supply a turn-on voltage to the gate of the silicon controlled rectifier.

Description

Electromagnetic wave thermostat for electric heater {A none electromagnetic wave heat controler for an electric heating bedding}

The present invention relates to a non-electromagnetic temperature controller for a heater used to be connected to the heater body as a connector for temperature control of the heater, and more particularly, it is possible to remove electromagnetic waves from the heater body without changing the structure of the heater body. The circuit is designed to make the temperature control circuit using the integrated circuit NE555, the frequency oscillator with switching and timing functions, harmless to the human body. Functions and functions of power saving, and by configuring the above circuit inside the temperature controller, if only the thermostat of the present invention is connected and connected without the improvement of the body of the heater, conventional electric heaters, such as electric blankets also remove the electromagnetic wave and the effect of power saving Non-electromagnetic thermostat for heater It's about the season.

Looking at the action of the heater body and the temperature controller, such as a conventional electric plate and electric yoke, a heating wire and a thermal wire for detecting the heat generated from the heating wire is coated with an insulator to form a cable of one heat generating unit to zigzag inside the heater body The heat generating cable has a heating wire and a heating wire, and the connection part of the heater has two ends of the heat generating part cable of inlet and withdrawal, so the connection port of the heater has four pieces of connecting pins to which four wires are connected. It is.

Then, a temperature controller is connected to the connection port of the heater body to adjust the temperature. Here, the thermal wire has a negative temperature coefficient characteristic. When the temperature of the heating wire increases, the resistance of the thermal wire decreases, and when the temperature of the heating wire decreases, the resistance of the thermal wire increases. Therefore, when the resistance of the thermal line is increased or decreased, the current flowing in the thermal line is reduced or increased, and the voltage at both ends of the capacitor of the bias circuit for applying a constant current pulse to the silicon-controlled rectifier supplying the current to the heating line is increased or decreased. The turn-on voltage of the silicon controlled rectifier will be lower or higher. When the turn-on voltage increases, the time for which the supplied voltage is applied to the heating line is delayed, so that a small amount of power is supplied to the heating line, and the temperature of the heating line decreases with time. In addition, when the temperature of the heating wire becomes low, a relatively large pulse current flows through the gate of the silicon control rectifier, and the timing at which the power supply voltage is applied to the heating wire is shortened, so that a larger amount of power is supplied to the heating wire, and the temperature of the heating wire is increased. It will increase over time.

In addition, the first method of the conventional electromagnetic shielding method is to connect the electromagnetic shielding circuit in parallel to the power supply circuit, which connects a resistor connected in series with the capacitor and the capacitor connected to one end of the supply power voltage to the ground terminal. A switch, a capacitor connected to the other terminal of the supply power supply voltage, and a switch for connecting a resistor and a resistor connected in series to the capacitor with a ground terminal are configured in an electromagnetic wave blocking circuit, and are connected in parallel to the main power supply circuit. Therefore, when an electromagnetic wave of positive or negative voltage is applied, each capacitor and resistor are connected to the ground terminal by each switch to block the electromagnetic wave of the positive region or the electromagnetic wave of the negative region.

In the second method, the electric heating plate or the electric yoke composed of the upper and lower thermal insulation layers overlapping each other by internally installing the heat generating unit cables inside the upper and lower thermal insulation bodies, the heat generating unit cable installed at the top and the heat generating unit cable installed at the bottom. Are arranged symmetrically and connected alternately to the power supply to reverse the direction of the current to cancel the electromagnetic waves.

The third method is to superimpose the heat generating cable with another electric conductor with different current direction and spiral direction to reduce the generation of electromagnetic waves at the same time as heat generation and to remove the electromagnetic wave leaked from the heat generating cable by grounding. .

The fourth method is to prevent electromagnetic waves by attaching an electromagnetic shielding agent such as a peeling plate or jade to the heater body.

As described above, the conventional heater has a structure to prevent electromagnetic waves in various ways, but the circuit, the heat generating unit cable or the heater body must be separately configured, and in reconfiguring the heater body, the symmetrical arrangement of the heat generating unit cable is required. Difficult to remove the electromagnetic wave using a shielding agent, but the electromagnetic wave constituting the electromagnetic wave can be removed, but the magnetic wave is difficult to remove.

The object of the present invention is to configure the circuit to prevent the generation of electromagnetic waves inside the temperature controller of the heater in order to remove the electromagnetic waves generated in the heater in view of the conventional problems as described above, the temperature control is efficient using the integrated circuit NE555 The present invention provides a non-electromagnetic thermostat for an electric heater having a temperature control circuit capable of saving power and forming the circuit in one chip.

1 is a detailed configuration of the temperature controller of the present invention

2 is a voltage pulse waveform diagram transmitted by the LLLD4422 chip of the present invention

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

Reference Signs List 1: terminal 2: connector 3: heater body

4: LLLD4422 chip 5: heating wire 6: thermal wire

7: heat generating cable 100: temperature controller

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

1 is an internal configuration diagram of a thermostat 100 of the present invention, the AC power is connected to the thermostat 100 through the terminal 1, the current output from the thermostat 100 is connected to the connector (2) It is supplied to the heater body 3 through the NE555 as a circuit comprising an integrated circuit for removing electromagnetic waves and temperature control (hereinafter referred to as LLLD4422 chip (4)), the light emitting diode (LED) and the resistor (R2) at the output of the NE555 ) Is connected in series to supply a turn-on voltage to the gate of the silicon controlled rectifier (SCR).

The connector 2 is composed of a connecting pin C11 and a connecting pin C22 connected to the heating line 5, and a connecting pin C12 and a connecting pin C21 connected to the thermal wire 6. The connecting pin C21 and the connecting pin C22 of the connection port 2 on the side of the temperature controller 100 are connected inside the LLLD4422 chip 4.

In addition, the LLLD4422 chip 4 is composed of NE555, resistors R3 (R4) (R5) and capacitors (D4) (D5), and becomes an oscillation circuit for transmitting voltage pulses of various cycles as necessary.

In the figure, reference numeral 7 denotes a heat generating cable which is arranged in a zigzag manner on the heater body and covers the heating wire 5 and the thermal wire 6.

The electromagnetic wave thermostat 100 for a heater according to the present invention, as described above, does not generate electromagnetic waves by the LLLD4422 chip 4 circuit including the NE555, thereby enabling efficient temperature control and power saving.

First, look at the power connection of the present invention, when the switch (S) is inserted, the current flows to the temperature controller 100 through the fuse (F), when the power is passed through the resistor (R1), the lamp (Lamp) is turned on, the temperature controller Indicates that power is connected to 100. After the switch S is connected, the power is lowered while passing through the capacitor C1, and the alternating current is rectified and stabilized by direct current while passing through the capacitor C2 and the diodes D1, D2, and D3. The circuit reaches NE555. The NE555 is a frequency oscillator that serves as switching and timing.

The voltage inputted to the AC power supply terminal 1 is rectified by half-wave rectification through the capacitor D1 and the capacitor D2, and combined to become full-wave rectified, and then converted to full DC by the capacitor D3 to the LLLD4422 chip 4. Power is supplied.

When power is supplied to the temperature controller 100 of the present invention as described above, the power supply is also connected to the heater body 3, such as an electric sheet and an electric yoke through the connector (2). The connection between the temperature controller 100 and the heater body 3 is the same as before, and the heater body 3 also uses a conventional one, but electromagnetic waves are generated in the heater body 3 by the temperature controller 100 of the present invention. I never do that. This is because the heating line 5 and the thermal line 6 inherent in the conventional heater body 3 is used, and the direction of the current flowing thereto is configured to be opposite to each other in the temperature controller 100 so that the electromagnetic waves cancel each other. . The electromagnetic wave removal in the present invention is as follows.

The inner conductor of the heat generating part cable 7 of the electric heater such as an electric field plate and an electric yoke is two lines, and has four pieces of connecting pins C11, C12, C21 and C22. That is, the heat generating cable 7 is composed of the heating wire 5 and the heating wire 6 for detecting the heat generated from the heating wire 5 are covered with an insulator, and the reciprocating arrangement in a zigzag manner is performed inside the heater body 3. Since the connection port 2 of the heater has both ends of the heat generating part cable 7 of the inlet and drawout, the four-piece connection pin C11 and C12 to which the four wires are connected to the connector 2 of the heater. C21) and C22 are formed. Therefore, when the temperature controller 100 and the heater main body 3 are connected, the two-piece connection pins C11 and C12 at the connection port 2 are connected to the power supply and the silicon control rectifier SCR to control the silicon control rectifier ( Electricity passes through the SCR, and the heater body 3 is heated, and the other two pieces of connecting pins C21 and C22 are connected inside the LLLD4422 chip 4, so that the current flowing through the connecting pin C11 is generated by a heating wire ( 5 to the connecting pin C22, and again through the connecting pin C21 to the connecting pin C12 along the thermal wire 6, the heating wire (5) inside the heat generating section cable (7) ) And the thermal line 6 are currents in opposite directions to each other. Thus, the electromagnetic waves are canceled out.

In particular, the feature of the present invention is to use the heater body 3 and the heat generating cable (7) installed therein as it is, which means that if only the temperature controller 100 of the present invention any conventional electric plate or electric yo This means that it can be used by connecting to a heater such as, it can be said to be differentiated from the conventional technology that removes electromagnetic waves by improving the heater body 3, including the temperature controller 100.

Next, the function of the temperature control and the power saving function of the present invention will be described. In the present invention, the heat radiation line 6 is used for electromagnetic wave removal, and the temperature control is not by the conventional heat radiation line 6 but by the LLLD4422 chip 4.

The temperature controller 100 uses the NE555, a frequency oscillator used for switching and timing, and controls the silicon controlled rectifier (SCR) to control the temperature rise of the heater body 3. That is, the NE555 and the resistors R3, R4, R5, diodes D4, D5, the variable resistor W outside the LLLD4422 chip 4, and the capacitor C4 are connected to each other. Periodic voltage such as is discharged, and the discharged voltage passes through the light emitting diode (LED) and the resistor (R2) to operate the silicon control rectifier (SCR) to heat the heater body (3).

The turn-on and turn-off of the silicon-controlled rectifier (SCR) that causes a current to flow in the heater body 3 is controlled by the LLLD4422 chip 4. The pulse length of the LLLD4422 chip 4 determines the temperature length of the heater body 3. That is, if the pulse emission of the LLLD4422 chip 4 is adjusted, the temperature of the heater body 3 is adjusted, and if the pulse is not discharged from the LLLD4422 chip 4, no current is supplied to the heater body 3 so that the purpose of power saving is achieved. Is achieved.

The width at which the LLLD4422 chip 4 emits pulses varies with the magnitude change of the intermediate resistance value of the variable resistor W, and the time for passing the electricity through the silicon controlled rectifier SCR also changes accordingly. That is, the time for which the heater body 3 is heated is also changed accordingly to achieve the purpose of temperature regulation.

2 is a voltage pulse emitted by the LLLD4422 chip 4, the voltage (V) has a period along the time axis, the period (T) is set to about 30 seconds, but can be used by itself. In FIG. 2, the area ratio {(V × t) / (V × T)} is referred to as the air content ratio, and as the air content ratio becomes larger, the temperature of the heater body 3 increases, and the maximum temperature when the air content ratio is 100%. Becomes

Therefore, the size of the area {V x t} in FIG. 2 is controlled by the variable resistor (W), which allows complete control of the highway ratio, and the oscillation period of the NE555 of the LLLD4422 chip 4 is about 30 seconds. To set. When the pulse is discharged from the NE555 of the LLLD4422 chip 4, the silicon controlled rectifier SCR is energized to raise the temperature of the heater body 3. Therefore, to control the highway ratio is to control the temperature of the heater body (3). When the pulse is not discharged, the silicon controlled rectifier (SCR) is not energized, so that the heater main body 3 is reduced in power and the temperature does not rise, thereby achieving the purpose of saving electricity.

Thus, the electromagnetic wave thermostat 100 for the heater of the present invention has the effect of preventing the generation of electromagnetic waves harmful to the human body, the effect of efficient temperature control by the voltage pulse wave, and the effect of power saving when the voltage pulse is not sent out In particular, the conventional heater can be used as it is, there is an effect that can be applied to the heater widely distributed in the general.

Claims (2)

A circuit for controlling temperature by the thermal wire 6 sensing the heat of the heating wire 5 and a connection port connected to the heater main body 3 by four-piece fins C11, C12, C21 and C22 ( In the temperature controller 100 of the electric heater composed of 2), the connection port 2 is a connection pin (C11) (C22) connected to the heating line (5) and a connection pin (C12) (C21) connected to the thermal radiation line (6). And a connection pin (C21) and a connection pin (C22) are connected to the inside of the LLLD4422 chip (4). The LLLD4422 chip (4) outputs a voltage pulse at the output of the NE555, and the power ratio is adjusted by a variable resistor (W), the voltage pulse being in series with a light emitting diode (LED) and a resistor (R2). Electromagnetic wave thermostat for the heater, characterized in that for controlling the temperature of the heater body (3) by supplying a turn-on voltage to the gate of the silicon control rectifier (SCR) connected to.