KR19980029572U - Electric bedding with non-magnetic thermostat - Google Patents

Abstract

The present invention relates to an electric bedding having a non-electromagnetic temperature controller that can extinguish electromagnetic waves harmful to the human body generated from an electric yoke, an electric blanket and the like by mutually flowing heating wires, and in an opposite direction inside the electric bedding 22. Electromagnetic waves are formed by the first heating wire 30 and the second heating wire 32 disposed and the temperature controller 20 connected to the first and second heating wires 30 and 32 to control AC power phase. Is a very useful design that can be eliminated and reduce manufacturing costs.

Description

Electric bedding with non-magnetic thermostat

In general, according to recent scientific papers, electromagnetic waves increase energy in the body, disrupting normal metabolism, such as thermoregulating hormone secretion, and disrupting the gene sequence, which greatly increases the incidence of brain leukemia in adults, brain cancer, and lymph cancer in adults. Reports have been issued, and the US Environmental Protection Agency (EPA) recently recommends the ban on the use of electricity bills or electric blankets.

Generally, as shown in FIG. 1, the electric bedding 8 is configured to generate heat by supplying alternating current power to the heating line 10, and the heating line 10 is formed at regular intervals in a zigzag in one row on the electrical bedding 8. ) And AC power is applied to the heating line 10 to generate heat.

However, as the heating wire 10 configured as described above generates heat, the alternating magnetic field is generated in the heating line 10 by the alternating current supplied to the heating line 10, and the alternating magnetic field is harmful to the human body. It is a factor that avoids the use of electric bedding (8) because it harms the health of the user.

In addition, the conventional electric bedding 8 has a relatively strong current voltage required for heating because the current flowing in the heating line 10 causes the commercial electricity to flow as it is, or in a product employing the temperature controller 18, a current of a sawtooth wave flows. In addition, when such a waveform flows on the heating line 10, electromagnetic waves are generated.

Meanwhile, in order to control the temperature of the electric bedding 8 described above, the temperature controller 18 shown in FIG. 2 includes a resistor R1, a capacitor C1, and a diode D1 in a reverse direction connected in series. The resistor R3 and the lamp LP are connected in parallel between the resistor R1 and the capacitor C1, and the variable resistors VR1 and VR2 and the resistor R2 are connected in series. . A drain of the SCR is connected in parallel with the resistor R1, and the gate of the SCR is connected to the code terminal H1 through the bidirectional triac TRIC and the diode D2.

The source of the SCR is connected to the capacitor C2 and the reverse diode D3, and is also connected to the terminal H3 to the terminal H4 through the smoke line 10. The anode of the diode D3 is connected to the terminal H4, and the terminal H4 is connected to the heating line 10 of the electric bedding 8.

The temperature controller 10 configured as described above removes the positive AC voltage at the point 2 passing through the reverse diode D1 and has only a negative value, and decreases the AC voltage passing through the variable resistors VR1 and VR2. The voltage applied to the terminal H1 is removed through the forward diode D2 and a negative value is applied to the gate of the SCR through the triac TRAIC. As described above, when the SCR is turned on by the pulse applied to the gate of the SCR, an AC voltage whose conduction angle of the SCR is adjusted is applied to the heating line 10.

If the temperature of the heating wire 10 laid on the bedding 8 increases, the variable resistance VR1 attached to the temperature controller 18 is increased to increase the pulse width applied to the gate of the SCR and to increase the conduction angle. The temperature of the heating line 10 is decreased by decreasing.

On the contrary, when the temperature of the heating wire 10 laid down on the bedding 8 decreases, the variable resistor VR1 attached to the temperature controller 18 is reduced to reduce the pulse width applied to the gate of the SCR and the conduction angle. Increase the temperature of the heating line 10 by increasing.

However, since the structure of the temperature controller 18 for controlling the temperature of the electric bedding 8 is complicated, there is a problem of increasing the manufacturing cost.

Recently, in order to solve the problems described above, the invention discloses that the magnetic field is canceled by dividing the current direction by dividing it into two loops inside and outside while maintaining an even heating line spacing. However, this invention is not only difficult to realize a complete magnetic field because the spacing of the heating wire is too large, it is difficult to realize a completely magnetic field as well as difficult to manufacture depending on the article to be applied due to the constraints such as parallel, equal intervals, alternating arrangement of the heating wire. there was.

An object of the present invention for solving the above problems is to provide an electric bedding having a non-electromagnetic wave temperature controller to extinguish the electromagnetic waves harmful to the human body generated from the heating wire.

Another object of the present invention is to provide an electric bedding having a non-electromagnetic temperature controller that currents flow in opposite directions to cancel each other.

In order to achieve the above object, the electric bedding having the electromagnetic wave thermostat of the present invention is connected to the first heating wire and the second heating wire which are disposed in opposite directions inside the electrical bedding, and are connected to the first and second heating wires. Characterized in that consisting of a temperature controller for controlling the AC power phase.

1 is a schematic diagram showing a heating wire disposed in a conventional electric bedding,

2 is a circuit diagram of a conventional thermostat,

3 is a schematic view showing the electric bedding of the present invention,

4 is a circuit diagram of a temperature controller of the present invention.

Explanation of symbols on the main parts of the drawings

R1, R2, R3: Resistor C1: Capacitor

VR1, VR2: Variable resistor TRAIC: Triac

As shown in FIG. 3, the temperature controller 20 for controlling the temperature of the electric bedding 22 by appropriately controlling the phase of the AC power supplied from the outside by the variable resistor VR1 and the temperature controller 20. It is composed of the first and second heating wires 30 and 32 which generate heat according to the controlled temperature of) and at the same time, close to each other and alternately close to each other and cancel the magnetic field by the current flowing in the opposite direction to reduce the generation of electromagnetic waves. .

And, as shown in Figure 4, the temperature controller 20 for properly adjusting the temperature of the electric bedding 22 is a fuse (FUSE) for blocking the AC power applied from the outside by overload, and the fuse (FUSE) A switch SW connected to the on / off temperature controller 20, a resistor R1 connected in parallel to the switch SW, and the operation of the temperature controller 20 when the switch SW is turned on. The first and second heating wires 30, which are connected to the lamp LP indicating a state and connected to the switch SW, are disposed in close contact with each other so that current flows in the opposite directions inside the electric bedding 22. 32, a variable resistor VR1, a variable resistor VR2, and a resistor R3 connected in parallel to the first and second heating lines 30 and 32, and connected in series to the resistor R3. Parallel to the capacitor (C1) and the variable resistor (VR1) for charging and discharging the external AC power to trigger the SCR It consists of connected resistance (R2) and, phase control means.

The phase control means includes an SCR for which an anode is connected to the first and second heating lines 30 and 32 to control an AC power according to the value of the variable resistor VR1, and a pulse connected to the gate of the SCR. It consists of two-way triac (TRAIC) that generates and conducts in both directions.

When the temperature controller 20 of the present invention configured as described above first turns on the power switch SW in a state in which an AC power is applied, the AC power is connected in parallel through a fuse FUSE and a power switch SW. Through R1), a lamp indicating the operation state is turned on.

Then, by adjusting the variable resistance (VR1) in the temperature controller 20 to adjust the appropriate temperature properly, the first and second heating wires (30) arranged to flow AC power in the opposite direction inside the electric bedding 22 , 32) the electric bedding 22 is heated to a set temperature.

At this time, if the size of the variable resistor VR1 connected to the first and second heating lines 30 and 32 is properly adjusted, a pulse is applied to the bidirectional triac TRAIC connected to the gate of the SCR. As such, the pulse passing through the TRIC is applied to the gate of the SCR to drive the SCR.

As described above, since the AC voltage is changed in accordance with the phase control of the SCR, when the temperature of the first and second heating lines 30 and 32 is lower than the temperature set in the variable resistor VR1, the first and second The value of the variable resistor R1 connected in parallel to the heating lines 30 and 32 is adjusted to be small. Then, when the voltage adjusted small by the variable resistor R1 is accumulated in the capacitor C1 and reaches a predetermined voltage or more, the SCR is discharged to conduct the SCR through the TRAC connected to the gate of the SCR. The phase angle of the SCR is reduced.

Therefore, the output voltage of the SCR is increased, so that more power is supplied to the first and second heating lines 30 and 32 to increase the temperature of the first and second heating lines 30 and 32.

On the other hand, when the temperature of the first and second heating wires 30 and 32 is higher than the temperature set by the variable resistor VR1 at first, it may be adjusted as described above. That is, when the value of the variable resistor VR1 connected in parallel to the first and second heating lines 30 and 32 is largely adjusted, the voltage regulated by the capacitor C1 is charged and then discharged when it reaches a predetermined value or more, so that the SCR The SCR is conducted by a pulse passing through the TRAC connected to the gate of the SCR, thereby increasing the phase angle of the SCR. As a result, the output voltage of the SCR is reduced, so that more power is supplied to the first and second heating lines 30 and 32, thereby reducing the temperature of the first and second heating lines 30 and 32.

Electric bedding having a non-electromagnetic thermostat of the present invention configured as described above, the electromagnetic wave is removed by the first and second heating wires disposed so that the current flows in the opposite direction, and the manufacturing cost is reduced by simplifying the configuration of the thermostat. It is devised to save.

The present invention relates to an electric bedding having a non-electromagnetic thermostat, and more particularly to an electric bedding having a non-electromagnetic thermostat capable of extinguished by smoke lines flowing in the opposite direction to the harmful electromagnetic waves generated in the electric yaw, electric blanket, etc. It is about.

Claims (5)

Phase control of the AC power supply is connected to the first heating line 30 and the second heating line 32 and the first and second heating lines 30 and 32 disposed in the opposite directions inside the electric bedding 22. Electric bedding having a non-electromagnetic thermostat, characterized in that consisting of a thermostat (20). 2. The electric bedding according to claim 1, wherein the first heating wire (30) and the second heating wire (32) are disposed in the electric bedding (22) in a zigzag form. The electric bedding according to claim 1, wherein the first heating wire (30) and the second heating wire (32) cancel electromagnetic waves by power flowing in opposite directions. The temperature controller of claim 1, wherein the temperature controller 20 includes a fuse R1 connected in parallel to the fuse FUSE and the switch SW, and a lamp LP indicating an operation state when the switch SW is turned on. ), The variable resistors VR1 and VR2 and resistor R3 connected in parallel to the first and second heating lines 30 and 32, and the variable resistors VR1 and VR2 and resistor R3. After the regulated voltage is charged, the capacitor C1 discharges when the voltage exceeds the predetermined voltage to trigger the SCR, the resistor R2 connected in parallel to the variable resistor VR1, and the variable resistor VR1. Electric bedding having a non-electromagnetic temperature controller, characterized in that the phase control means for controlling the phase in accordance with the value. 5. The phase control means according to claim 4, wherein the phase control means includes an SCR whose anode is connected to the first and second heating lines 30 and 32, and the voltage stored in the capacitor C1 is equal to or greater than a predetermined value. The electric bedding having a non-electromagnetic temperature controller, characterized in that consisting of a bidirectional triac (TRAIC) that is discharged when the pulse is applied to the SCR.