KR19990021747A - Electromagnetic field removal structure of electrothermal insulator - Google Patents

Abstract

The present invention is an electric field (magnetic field) and a magnetic field (generated) generated in the electric heat preservatives such as electric blanket, electric blanket, electric blanket, electric cushion using a heating wire wrapped with shielding means for shielding on the outer circumferential surface of the heating wire that generates heat ( Iv) The electromagnetic field removal structure of the heat preservation heater for removing the heat insulator, and in particular, the insulator is arranged so that the outer circumferential surface of the heating element (carbon glass fiber or multi-core linear heater) consisting of a plurality of lines to form a straight line completely wrapped. The first heating wire 20 ′ and the second heating wire 20 having the same characteristics formed by closely contacting the cylindrical shielding means are equally arranged in the heat insulating body, and when the power source of which one side of the power line is grounded is applied, the ground The connected power supply line to the second contact point 32, the other power supply line to the first contact point 31, the third contact point 33 and the fifth contact point 35, and the fourth contact point 34 ) And the sixth contact 36, the seventh When the power source is connected to the contact point and the eighth contact point 38 and neither of the power lines is grounded, the first contact point 31 and the second contact point 32 are connected, and the fourth contact point 34 ) And the sixth contact 36, the seventh contact 37 and the eighth contact 38 is connected, and both power lines of the power supply to the third contact 33 and the fifth contact 35, respectively It is an electromagnetic field removing structure of an electric heat preservative characterized by a junction box.

The present invention has the effect of being able to remove the electric and magnetic fields generated in the heat preservation heater.

Description

Electromagnetic field removal structure of electrothermal insulator

The present invention is a heating wire wrapped with shielding means (collecting a shielding wire, or a shielding net, or a shielding tube wrapped along the outer circumferential surface of the heating wire) for shielding the heating wire outer peripheral surface for generating heat, or a heating wire and a detection wire and shielding Electric field generated from a warmer (hereinafter, referred to as a heat insulation), such as an electric blanket, an electric blanket, an electric blanket, and an electric cushion, which generate heat by using heating wires (hereinafter, all called heating wires) that are surrounded by means. ) Is related to the electromagnetic field removal structure of the heat insulation thermostat for removing a magnetic field (hereinafter, referred to as an electric field combined with an electric field and an electric field), and in particular, a power supply having one side of the : In the case of single-phase two-wire power supply, connect the heating wire and the same end of the shielding means, and apply a power supply so that the ground potential is connected to the shielding means of the other end, neither of which is grounded. In the case of a power supply (for example, a single-phase three-wire power supply), by connecting both ends of the heating wire and the shielding means, and cutting the two points of the heating wire and applying the power therethrough, the electric field generated from the heat insulation is It is shielded and removed by shielding means, and the magnetic field is to cancel out by mutually canceling the magnetic field generated by the shielding means.

As is well known, the electrothermal warmer is composed of a heating element for generating heat and a temperature controller for controlling the heating temperature of the heating element to perform an operation for generating heat of a predetermined temperature set by a user.

That is, as shown in FIGS. 1 and 2, the heating wire 10 formed of the nylon thermistor 13, the detection wire 14, and the insulating PVC layer 15 which are sequentially wrapped on the outer circumferential surface of the heating wire 12 generating heat. After arranging at equal intervals with respect to the entire heat insulation thermostat, by maintaining a temperature set by the user by controlling the power supplied to the heating wire 10 through a temperature controller (not shown).

Here, the nylon thermistor 13 is an insulator for insulating between the heating wire 12 and the detection wire 14, the reference numeral 1 in the drawing (1) is a power connection terminal, (11) is the heating wire 12 Each of the wound cores is shown, and the power applied through the power connection terminal 1 flows in the direction of the arrow (or the direction opposite to the arrow) to generate heat.

However, such a conventional heat insulator has an electric field around the heating wire 10 due to the flow of a current having one direction (the flow of current flowing in the direction of the arrow or the direction opposite to the arrow by the power source frequency (50 Hz to 60 Hz)). There was a problem that the formation has a fatal adverse effect on the human body.

That is, as shown in FIG. 3, when the current I flows through the conductor, a magnetic field B and an electric field are generated around the conductor, as revealed by OERSTED or Ampere. By the same principle, the magnetic field (B) and the electric field formed on the heating wire 10 of the heat preservation heater randomly stimulates the blood of the human body, and interferes with the flow of the air, causing a blood circulation disorder, Fatigue was aggravated, and in severe cases there was a problem that will cause a stroke.

In other words, the electromagnetic field generated in the conventional heat insulating device destroys the rhythm of the body, which is a microenergy which is difficult to detect by a mechanical mechanical measuring instrument. Since the human body does not have a natural electromagnetic field that is suitable for such an electric field, The negative effect on the nervous system of the person as it is used, resulting in the destruction of living cells of the human body caused various dermatitis and headache, chronic fatigue, menstrual irregularities, premature birth, birth defects and paralysis.

Therefore, as in the Korean Utility Model Registration Application No. 93-19696, which is the applicant's prior application, the electric field is shielded by covering the entire heat shield with a shielding net, and as in Utility Model Registration Application No. 94-7734, the straight type A cylindrical shielding wire is formed to surround the outer circumferential surface of the carbon glass fiber, which is a heating element, and the same ends of the carbon glass fiber and the shielding wire are connected, and power is applied to the other end. A method of canceling a magnetic field by allowing the directions of currents flowing in opposite directions to cancel each other so that the magnetic fields generated in the carbon glass fiber and the shielded wire cancel each other.

However, the conventional method of removing electric and magnetic fields has a problem that the manufacturing cost increases and the work process becomes complicated due to the use of both methods to remove the electric and magnetic fields generated from the heat preservation heater. there was.

That is, in order to remove the electromagnetic field generated from the heat-insulating device, after canceling the electric field using the method according to the Utility Model Registration Application No. 94-7734, or Patent Application 96-48224, Utility Model Registration Application No. 93 -Since the electric field must be shielded using the method according to No. 19696, there are problems such as increased cost and complicated manufacturing process due to the installation of the shielding network.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned conventional problems. Particularly, when one side of the power supply line is grounded, the ground potential is connected to the shielding line at the other end after connecting the same end of the heating line and the shielding line. In the case of a power source that is supplied with power and neither of the power lines is grounded, connect the two ends of the heating line and the shielding line respectively, and cut the two points of the heating line and apply the power through this. The electric field is shielded and removed by the shielding means, and the magnetic field is canceled by mutually canceling with the magnetic field generated by the shielding means, thereby providing an electromagnetic field removing structure of the electric heat preservative that can remove the electric field generated in the heat preservative. have.

In order to achieve the above object, configuration 1 of the electromagnetic field removing structure of the present invention heat insulation thermostat is composed of a plurality of wires to form an insulator so that the outer circumferential surface of the heating element (carbon glass fiber, or multi-core linear heater) in a straight line form is completely wrapped. Cylindrical shielding means (shielded wires) are formed in close contact with each other, and the same ends of the heating element and the shielding means are connected to each other, and a current flowing through the heating element and the shielding means is applied to one side of the power line through the other end. In the electric heat preservation apparatus in which the heating wires are arranged to be equal to the electric heat preservation body so that the magnetic fields generated by the heating element and the shielding means are mutually canceled by making the directions of

The connection of the power applied through the other end of the heating wire is characterized in that the technical configuration is configured by connecting the grounded power supply line of the power supply is grounded on one side of the power supply line is applied to the shielding means.

According to the configuration 1 of the present invention, the magnetic field generated in the heat preservation heater is canceled out by mutually reversed current flowing through the shielding means and the heating element, and the electric field is connected to the shielding means surrounding the heating element. It is removed by shielding by the wire, and thus it is possible to remove the magnetic field and the electric field generated in the electrothermal warmer without a separate shielding means.

On the other hand, the configuration 2 of the electromagnetic field removing structure of the heat insulating thermostat of the present invention, the shielding means of the cylindrical through the insulator so that the outer circumferential surface of the heating element (carbon glass fiber, or multi-core linear heater) made of a multi-line to form a straight line completely wrapped After the shielding wire is formed in close contact, the same ends of both sides of the heating element and the shielding means are connected, and a half point of the heating element is cut, and neither of the power lines is grounded through both ends of the cut heating element. It is characterized by the technical configuration that the heating wires to which power is applied are arranged evenly on the body of the heat insulating body.

According to the configuration 2 of the present invention, the electric field generated by the heat preservation heater is connected to both ends of the shielding means and the heating element, and then shielded to form a virtual ground point by the power applied through the 1/2 point of the heating element. It is shielded and removed by means, the magnetic field is canceled by mutually canceled by the reverse current flowing in the shielding means and the heating element, thereby removing the magnetic field and the electric field generated in the heat insulating body without a separate shielding means Will be.

On the other hand, configuration 3 of the electromagnetic field removing structure of the present invention is a cylindrical shielding means through the insulator so that the outer circumferential surface of the heating element (carbon glass fiber, or multi-core linear heater) made of a multi-line to form a straight line completely wrapped The first heating wire and the second heating wire having the same characteristics formed in close contact with the shielding wire are evenly arranged in the heat insulating body, and the shielding means at one end of the first heating wire is the first contact point and the heating element is the second contact point. The shielding means of the other end of the first heating wire is the third contact, the heating element is the fourth contact, the shielding means of the one end of the second heating wire is the fifth contact, the heating element is the sixth contact, and the one end of the second heating wire is When the shielding means is a seventh contact point and the heating element is an eighth contact point, when a grounded power source is applied, the grounded power supply line is connected to the second contact point, and the other power supply line is connected to the first contact point. Connection , When the third contact point and the fifth contact point are connected, the fourth contact point and the sixth contact point are connected, the seventh contact point and the eighth contact point are connected, and when a power source is applied to which neither of the power lines is grounded. Connect the first contact point to the second contact point, connect the fourth contact point to the sixth contact point, connect the seventh contact point to the eighth contact point, and connect both power lines of the power supply to the third contact point and the fifth contact point, respectively. It is characterized by the technical configuration. In the connection of the first to eighth contacts, the fourth contact and the sixth contact are connected, and the seventh contact and the eighth contact are connected, and then the first contact, the second contact, and the third contact are And the fifth contact point is switched using a predetermined switching means.

The switching means may include: a ground discriminating unit which detects whether the applied power is grounded, outputs a signal indicating when the power is not grounded, and outputs a signal indicating when one side of the power is grounded; It is composed of a plurality of switches, it is characterized in that it is connected to the signal output terminal of the ground discriminating unit, it comprises a switch unit for performing a switching operation according to the signal applied from the ground discriminating unit.

The switch part includes first to fourth switches having three contact points a, b, and c and a common connection point d. The switch unit connects a second contact point of the first heating wire to a contact point of the first switch. The first contact point of the first heating wire is connected to the contact point a of the switch, the third contact point of the first heating wire is connected to the contact point a of the third switch, and the fifth contact point of the second heating wire is connected to the common connection point d of the third switch. Connect a contact point, connect a contact point of the first switch to b contact point of the second switch, connect a contact point of the first switch to the common connection point d of the fourth switch, and b contact point of the first switch. A contact point of the second switch, a c contact point of the first switch to a contact point of the third switch, a common connection point d of the first switch to one terminal of a power supply, and a contact point is connected to c contact point of the fourth switch, and The c contact point of the second switch is connected to the c contact point of the third switch, the common connection point d of the second switch is connected to the other terminal of the power supply, and the a contact point of the third switch is connected to the b contact point of the third switch. Characterized in that configured.

The first switch to the fourth switch is characterized in that the same switch at the same time by the signal applied from the ground discriminating unit.

Here, the ground discriminating unit is configured in the same manner as the technical spirit described in detail in the patent application No. 94-7734 and Patent Application Nos. 97-15860 of the prior application of the present invention, the detailed description thereof will be omitted.

In the configuration 3 of the present invention, the ground discrimination unit detects whether the power is grounded, and in the case of a power source in which neither of the power lines is grounded, the operation of the switch unit is controlled to make the same connection as in configuration 2, If it is determined that one side is a grounded power supply is to control the operation of the switch unit to make the same connection as the configuration 1.

In other words, by automatically (or manually) switching the switch of the switch unit by determining whether the power is grounded, thereby eliminating the electric and magnetic fields generated by the heat insulating device regardless of whether the power is grounded. will be.

1 is a perspective view showing the structure of a conventional heating wire,

Figure 2 is a partial cutaway perspective view showing the configuration of a heat insulation using a conventional heating wire,

3 is a view showing a magnetic field formed by the right-hand law of amperes,

Figure 4 is a view showing the configuration of the heating wire of the electromagnetic field removing structure of the present invention,

4A is a perspective view,

4b is a side cross-sectional view,

4C is a front cross-sectional view,

Figure 5 is a partial cutaway perspective view showing the configuration of the heat insulation using the heating wire according to the configuration 1 of the present invention,

6 is a cross-sectional view showing a method for connecting a heating wire according to Configuration 1 of the present invention;

7 is a cross-sectional view showing a connection method of a heating wire according to the configuration 2 of the present invention;

Figure 8 is a partial cutaway perspective view showing the configuration of the heat insulation using a heating wire according to the configuration 2 of the present invention,

9 is a cross-sectional view showing a method for connecting a heating wire according to Configuration 3 of the present invention;

10 is a block diagram showing a configuration example of a switching means according to Configuration 3 of the present invention;

FIG. 11 is a view schematically showing a configuration of a switch unit according to Configuration 3 of the present invention. FIG.

Explanation of symbols for main parts of the drawings

1: power connection terminal 20: heating wire

21 carbon glass fiber 22 inner insulator

23: shielded wire 24: external insulator

20 ': first insulated wire 20: second heating wire

31: first contact point 32: second contact point

33: third contact point 34: fourth contact point

35: fifth contact 36: sixth contact

37: 7th contact 38: 8th contact

40: ground discriminating unit 50: switch unit

51: first switch 52: second switch

53: third switch 54: fourth switch

a, b, c: contact point d: common connection point

Hereinafter, an embodiment according to the technical concept of the electromagnetic field removing structure of the present invention, the configuration, operation and effect will be described in detail with reference to the accompanying drawings.

Example 1

The present Example 1 shows an embodiment according to the configuration 1 of the electromagnetic field removing structure of the present invention, and relates to the electromagnetic field removing structure of the heat insulation warmer using a power supply (eg, a single-phase two-wire power supply) that is grounded on one side of the power supply line. will be.

First, the heating wire used in the present embodiment will be described.

The heating wire used in the present embodiment is a heating wire set forth in Korean Patent Application No. 96-48224, which is a prior application of the present invention, which comprises a linear heating element and a cylindrical shielding wire (shielding means) completely covering the linear heating element. .

That is, as shown in Figs. 4A and 4B, the shielded wire of the cylindrical shape is arranged so that the carbon fiber fibers 21 of the plurality of lines are arranged in a straight line to form a linear heating element, and the outer circumferential surface of the carbon glass fiber 21 is completely wrapped. 23 is formed in close contact with each other, and an inner insulator 22 made of silicon rubber is inserted between the carbon glass fibers 21 and the shielded wires 23 to insulate. In addition, an outer insulator 24 made of silicon rubber is formed on the outer circumferential surface of the shielded wire 23, and the carbon glass fiber 21 and one side end of the shielded wire 23 are connected to each other.

Here, the reason for configuring the multi-wire carbon glass fiber 21 is to prevent the disconnection caused when folding or moving the heat insulating thermostat, the shielded wire 23 is a copper wire in the network form The carbon glass fiber 21 is to be wrapped.

Subsequently, as shown in FIG. 5, the heating wire 20 is arranged to be equally heated on the heat insulating body, and then the carbon glass fiber is connected through a power connection terminal 1 to which a temperature controller (not shown) is connected. Power is applied to the other end of the 21 and the shielded wire 23.

In this case, when one side of the power line is connected to grounded power, power is applied such that the grounded power line of the power source is connected to the shielded wire as shown in FIG.

Then, the power connection terminal 1 (grounded power line) → shielded wire 23 → carbon glass fiber 21 → power connection terminal 1 (ungrounded power line) and power connection terminal 1 ( A non-grounded power line) → a carbon glass fiber 21 → a shielded wire 23 → a power closing terminal 1 (grounded power line) is formed a current closed circuit is heated to heat the thermal insulation. At this time, the carbon glass fiber 21, as shown in Figure 4c, a magnetic field in the direction of the arrow (or the opposite direction of the arrow) according to the law of ampere is formed.

In the same principle, the shielded wire 23 is also provided with a magnetic field in the direction of the arrow (or the direction opposite to the arrow).

However, the magnetic fields formed on the carbon glass fibers 21 and the shielded wires 23 are magnetic fields having rotation directions in opposite directions to each other, and therefore, the magnetic fields formed on the carbon glass fibers 21 and the shielded wires 23. This will be mutually offset.

That is, the linear heating element is formed of the multi-line carbon glass fibers 21 to form the magnetic field having the same direction on the same straight line, and the magnetic field having the same direction on the same straight line is formed through the cylindrical shielded wire 23. Then, by connecting the same end on one side to form a single closed path for the power source, the direction of the magnetic field generated in the carbon glass fiber 21 and the shielded wire 23 is to be opposite to each other.

Therefore, the magnetic fields of the carbon glass fiber 21 and the shielded wire 23 having the same center, the same size, and opposite directions at close distances are mutually cancelled.

On the other hand, the electric field generated by the current flowing through the carbon glass fiber 21, which is a heating wire, is induced in the shielded wire 23 surrounding the carbon glass fiber 21, and the electric field induced in the shielded wire 23 The silver is discharged to the ground through the power line grounded to the shielded wire (23).

This will be described in detail as follows.

As is well known, a power supply having one side of the power supply line grounded means a power supply in which one of the two lines of power supply lines to which the power supply is applied is connected to the ground potential point, and is a single-phase two-wire 110V power supply or Y For example, the power supplied through one of the Y wires and the neutral point can be used.

That is, in the 110V commercial power supply to the home, any one of two lines of power lines is connected to the ground through the ground terminal of the transformer, and the center point of the Y connection is also connected to the ground.

Therefore, when the power line connected to the ground is connected to the shielded wire 23, the potential of the shielded wire 23 becomes the ground potential, and the induced electric field is the grounded power source connected to the ground. It is emitted along the line to the ground potential point (ground), so that the electric field is not emitted outside the shielded wire 23.

That is, the shielded wire 23 serves to remove the external emission of the electric field by playing the same role as the shielding network of Utility Model Registration No. 93-19696, thereby eliminating the electric and magnetic fields emitted to the outside of the thermal insulation. It will be possible.

Example 2

The present Example 2 shows an embodiment according to the configuration 2 of the electromagnetic field removing structure of the present invention, the electromagnetic field removing structure of the heat insulation warmer using a power source (eg, single-phase three-wire power supply) that is not grounded to any of the power supply line It is about.

First, as in Example 1, the linear carbon heating fibers 21 arranged in a straight line to form a linear heating element, and the cylindrical shielded wire 23 so that the outer peripheral surface of the carbon glass fibers 21 is completely wrapped It is formed in close contact, and the insulation is made by inserting the inner insulator 22 made of silicon rubber between the carbon glass fiber 21 and the shielded wire (23). In addition, an outer insulator 24 made of silicon rubber is formed on the outer circumferential surface of the shielded wire 23.

Then, as shown in Figure 7, after connecting the same end of both sides of the carbon glass fiber 21 and the shielded wire 23, and cut half of the point of the carbon glass fiber 21, cutting Power is applied to both ends of the power supply (eg, single-phase three-wire power supply) that is not grounded at both ends.

That is, as shown in Figure 8, by connecting the same end of both sides of the heating wire 20 arranged to be equally heated to the body of the heat insulating body, and then to the power connector 1 is connected to the temperature controller (not shown) Power is applied to both ends of the carbon glass fiber 21 through which neither of the power lines is grounded.

Then, the power connection terminal 1 (power supply line 1 of the ungrounded power supply) → carbon glass fiber 21 → shielded wire 23 → carbon glass fiber 21 → power connection terminal 1 (ungrounded Power supply line 2) and power connection terminal (1) (non-grounded power supply line 2) → carbon glass fiber (21) → shielded wire (23) → carbon glass fiber (21) → power connection terminal (1) A current closed circuit consisting of (No. 1 power supply line of the ungrounded power supply) is formed to heat the heat preservation heater.

At this time, the carbon glass fiber 21, as shown in Figure 4c, a magnetic field in the direction of the arrow (or the opposite direction of the arrow) according to the law of ampere is formed.

In the same principle, the shielded wire 23 is also provided with a magnetic field in the direction of the arrow (or the direction opposite to the arrow).

However, the magnetic fields formed on the carbon glass fibers 21 and the shielded wires 23 are magnetic fields having rotation directions in opposite directions. As in Example 1, the carbon glass fibers 21 and the shielded wires 23 are used. The magnetic fields formed in) will cancel each other out.

That is, by connecting both ends of the carbon glass fiber 21 and the same end of the shielded wire 23, and applying power through a cut portion 1/2 of the carbon glass fiber 21, the carbon glass fiber that is the power application point ( Magnetic fields having opposite directions to each other are formed on the same straight line on the basis of 1/2 point of 21), and 1/2 point of the cylindrical shielded wire 23 (1/2 point of the carbon glass fiber 21). The magnetic fields having opposite directions to each other are formed on the same straight line on the basis of), so that the directions of the magnetic fields generated in the carbon glass fiber 21 and the shielded wire 23 are opposite to each other.

Therefore, magnetic fields generated in the carbon glass fiber 21 and the shielded wire 23 having the same center, the same size, and opposite directions at close distances are mutually offset.

On the other hand, the electric field generated by the current flowing through the carbon glass fiber 21, which is the smoke line, is organically removed from the carbon glass fiber 21 forming the virtual ground potential.

This will be described in detail as follows.

As is well known, a power supply in which neither of the power lines is grounded refers to a power supply in which two lines of power supply lines to which power is applied are not connected to the ground potential point. The power supplied without using the neutral point, that is, the 220V power supply (single-phase three-wire power supply) supplied through any two of the three power lines forming the Y connection, or the power applied through both ends of the delta connection. For example.

That is, in the case of the single-phase three-wire power supply that supplies power through the Y connection, among the 220V commercial power supplies to the home, neither of the two lines of power supply lines that supply power is grounded to the ground. Therefore, both power lines maintain a voltage of 110V with respect to the earth ground potential.

Therefore, in the case of such a power supply, a virtual ground point may be created to prevent external emission of the electric field. As in the second embodiment, after connecting both ends of the carbon glass fiber 21 and the shielded wire 23, which are heating wires, When the half point of the carbon glass fiber 21 is cut and the single-phase three-wire power is applied thereto, the shielded wire 23 connecting both cut portions of the carbon glass fiber having an equivalent resistance is Will have a virtual ground potential.

This is the same principle as forming a virtual ground point by applying a zero power to the common connection point of the resistor when AC power is applied through both ends of the unconnected resistor after series connection of a resistor having the same value.

That is, since the resistance value of the shielded wire 23 is a negligible value compared to the resistance value of the carbon glass fiber, the entire shielded wire 23 becomes a zero potential to become a virtual ground point.

Therefore, the electric field generated from the carbon glass fiber is shielded by a shielded wire having a virtual ground potential, so that the electric field is not emitted outside the shielded wire.

That is, the shielded wire to remove the external emission of the electric field by playing the same role as the shielding network of Utility Model Registration No. 93-19696, thereby eliminating the electric and magnetic fields emitted to the outside of the heat insulating thermostat. will be.

Example 3

Embodiment 3 shows the embodiment according to the configuration 3 of the electromagnetic field removing structure of the present invention, so that the power supply structure applied to the heating wire by determining whether the power line is grounded as in Example 1 or Example 2 Therefore, the present invention relates to an electromagnetic field removing structure of an electric heat preservative that can be used regardless of whether the power line is grounded.

First, as shown in FIG. 9, the fourth contact 34 of the first heating wire 20 ′ and the sixth contact 36 of the second heating wire 20 are connected, and the second heating wire 20 is connected to the fourth contact point 36. After the seventh contact 37 and the eighth contact 38 are connected, as shown in Fig. 10, the switch section 50 is connected by the ground discriminating section 40 to operate.

Thereafter, as shown in FIG.

The second contact point of the first heating wire 20 'is connected to the contact point a of the first switch 51, and the first contact point 31 of the first heating wire 20' is connected to the contact point a of the second switch 52. , The third contact 33 of the first heating wire 20 'to the contact point a of the third switch 53, and the second heating wire 20 to the common connection point d of the third switch 53. To the fifth contact 35 of the first switch 51, the a contact point of the first switch 51 is connected to the b contact point of the second switch 52, and the a contact point of the first switch 51 is connected to the fourth switch 54. The contact point b of the first switch 51 to the contact point a of the second switch 52, and the contact point c of the first switch 51 to the contact point a of the third switch 53. , The common connection point d of the first switch 51 is connected to one terminal of the power supply, the a contact point of the second switch 52 is connected to the c contact point of the fourth switch 54, and the second switch ( The c contact point of the second switch 52 is connected to the c contact point of the third switch 53, and After connecting the connection point d to the other terminal of a power supply, connecting the a contact point of the 3rd switch 53 to the b contact point of the 3rd switch 53, the switching control terminal of the said 1st switch-the 4th switch, The third embodiment is configured by connecting to the signal output terminal of the ground discriminating unit 40. FIG.

Here, the ground discriminating unit is configured in the same manner as the technical idea described in detail in the first application Utility Model Registration Application Nos. 94-7734 and Patent Application Nos. 97-15860, and the detailed description thereof is omitted.

Then, according to the signal applied from the ground discriminating unit 40, the connection as in the first embodiment, or the connection as in the second embodiment is made to remove the electromagnetic field generated in the heat insulation.

That is, when it is determined that power is not grounded on either of the power lines, the second contact point 32 and the first contact point (s) are switched to the c contact points of the first to fourth switches of the switch unit 50. After connecting 31), power is applied through the third contact 33 and the fifth contact 35 to form the connection structure as in the second embodiment, thereby removing the electromagnetic field.

In addition, when a grounded power supply is applied to one side of the power supply line, it is determined which power supply line is the grounded power supply line. When the power supply line connected to the common connection point d of the first switch 51 is a grounded power supply line, When the power line connected to the common contact point d of the second switch 52 is switched to the contact points a of the first to fourth switches of the switch unit 50, the switch unit 50 By switching to the b contact point of the first switch to the fourth switch of), the third contact point 33 and the third contact point 35 are connected to remove the electromagnetic field in the same connection structure as in the first embodiment. .

However, in the third embodiment, the operation of the switch unit is described as being automatically switched by a signal applied from the ground discriminating unit, but it is understood that the switching can be performed manually according to the result determined by the ground discriminating unit.

As described above, the electromagnetic field elimination structure of the heat insulation thermostat according to the present invention includes a heating wire formed by closely contacting a cylindrical shielding means through an insulator so that the outer circumferential surface of the heating element, which consists of a plurality of lines, is completely enclosed. By connecting as in the configuration 1, configuration 2 or configuration 3 depending on whether or not, there is an effect that it is possible to remove the electric and magnetic fields generated in the heat preservation heater.

Claims (7)

Cylindrical shielding means is formed in close contact with the insulator so that the outer circumferential surface of the heat generating element, which is made up of multiple lines and forms a straight line completely, is connected to one end of the heating element and the shielding means, and one side of the power line through the other end. By applying this grounded power so that the direction of the current flowing through the heating element and the shielding means to be opposite to each other, the heating element which is arranged evenly on the body of the heat preservation body so that the magnetic field generated by the heating element and the shielding means mutually canceled. , Connection of the power applied through the other end of the heating wire, the grounded power supply line of the power supply is grounded on one side of the power supply line, characterized in that configured to be connected to be applied to the shielding means. After the cylindrical shielding means is formed in close contact with the insulator so that the outer circumferential surface of the heat generating element, which is made up of a plurality of lines, is completely enclosed, the same ends of both sides of the heat generating element and the shielding means are connected to each other. The electric field removing structure of the heat preservation heat exchanger characterized in that it is configured to equally arrange the heating wire to which the power supply which is not grounded at any of the power supply line through both ends of the cut heating element to the heat preservation body. The first heating wire and the second heating wire of the same characteristics formed by closely insulated the cylindrical shielding means through the insulator so that the outer circumferential surface of the heating element which consists of a plurality of lines to form a straight line are completely wrapped in the heat insulating body. The shielding means at one end of the first heating wire is the first contact point, and the heating element is the second contact point, The shielding means at the other end of the first heating wire as the third contact point and the heating element as the fourth contact point, The shielding means at one end of the second heating wire is the fifth contact point, and the heating element is the sixth contact point, When the shielding means at one end of the second heating wire is referred to as the seventh contact point and the heating element as the eighth contact point, When one side of the power line is grounded, Connect the grounded power supply line to a second contact point, Connect the other power line to the first contact point, Connect the third contact and the fifth contact, Connect the fourth and sixth contacts, Connect the 7th contact and 8th contact, If a power source is applied that is not grounded on either side of the power supply line, Connecting the first contact and the second contact, Connect the fourth and sixth contacts, Connect the seventh and eighth contacts, The electromagnetic field removing structure of the heat insulation thermostat, characterized in that both power lines of the power supply are connected to the third contact point and the fifth contact point, respectively. The method of claim 3, wherein the connection of the first to eighth contact, After connecting the fourth contact point and the sixth contact point, and connecting the seventh contact point and the eighth contact point, By switching the first contact, the second contact, the third contact, and the fifth contact by using a predetermined switching means, When one side of the power line is grounded, The grounded power line is connected to a second contact point, Make sure the other power line is connected to the first contact point, The third and fifth contacts are connected, If a power source is applied that is not grounded on either side of the power supply line, The first contact point and the second contact point are connected, An electromagnetic field removing structure of an electric heat preservative, characterized in that both power lines of the power supply are connected to the third contact point and the fifth contact point, respectively. The grounding apparatus of claim 4, wherein the switching unit detects whether the applied power is grounded, and outputs a signal indicating when the power is not grounded, and outputs a signal indicating when one side of the power is grounded. A discriminating unit; The electromagnetic field removing structure of the heat preservation heater, comprising a plurality of switches, connected to the signal output terminal of the ground discriminating unit, the switch unit performing a switching operation according to the signal applied from the ground discriminating unit. The method of claim 5, wherein the switch unit is composed of first to fourth switches having three contact points a, b, c and a common connection point d, A second contact point of the first heating wire is connected to a contact point of the first switch, A first contact point of the first heating wire is connected to a contact point of the second switch, A third contact point of the first heating wire is connected to a contact point of the third switch, The fifth contact of the second heating wire is connected to the common connection point d of the third switch, A contact point of the first switch is connected to b contact point of the second switch, A contact point of the first switch is connected to a common connection point d of the fourth switch, Connect b contact point of the first switch to a contact point of the second switch, Connect c contact point of the first switch to a contact point of the third switch, The common connection point d of the first switch is connected to one terminal of the power supply, A contact point of the second switch is connected to c contact point of the fourth switch, Connect c contact point of the second switch to c contact point of the third switch, The common connection point d of the second switch is connected to the other terminal of the power supply, And a contact point of the third switch connected to the contact point b of the third switch. The structure of claim 6, wherein the first switch to the fourth switch are configured to be automatically and manually switched at the same time by a signal applied from the ground discriminating unit. 7.