KR20130001212U - Heating cable - Google Patents

Abstract

The present invention relates to a heating wire to block the electric field, more specifically, to reduce the synthetic resistance by adding an aluminum plate on the outer portion of the double heating wire to block the electric field leaking from the heating wire used for electric yoke or electric sheet, The electric field cut-off heating wire of resistance reduction per unit length for the potential difference of the heating wire surface to apply the average voltage below 10V. The present invention utilizes an aluminum plate and an aluminum film to reduce the resistance applied to the second heating wire, thereby lowering the average voltage applied to the rear end of the second heating wire to 10 V or less, thereby providing a heating wire to remove the electric field. . In addition, the present invention uses a flat non-heating heating wire, widening the winding range of the second non-heating heating wire, reducing the leakage of the electric field generated in the first heating wire, aluminum plate, aluminum on the second non-heating heating wire A wider contact with the film provides a tighter seal, providing a heating wire that enhances the field removal performance.

Description

Resistance reduction electric field blocking heating wire per unit length {Heating cable}

The present invention relates to a heating wire to block the electric field, more specifically, to reduce the synthetic resistance by adding an aluminum plate on the outer portion of the double heating wire to block the electric field leaking from the heating wire used for electric yoke or electric sheet, The electric field cut-off heating wire of resistance reduction per unit length for the potential difference of the heating wire surface to apply the average voltage below 10V.

Common heating wires used as heating elements in electric heating devices, such as electric blankets, electric mats or poultice mats, generally include a ventricle made of polyester thread or glass wool, a first heater coil spirally wound on the ventricle, and insulated on the heater coil. The inner insulator coated for insulation, the second heater coil on the outer circumferential surface of the inner insulator, the second inner insulator coated on the outer circumferential surface of the second heater coil, and the outer circumferential surface of the second inner insulator in the form of a wire or a net And a shield to be grounded, and an outer insulator coated on the shield.

In the above configuration, the first heater coil and the second heater coil are electrically connected in series with each end thereof, and each of the tips thereof is a power input terminal respectively connected to the positive (+) terminal of the power source.

Since electricity flows through the heating line, an electric field is generated. The electric wave has a bad effect on the human body, it is very important to block the electric wave in bedclothes and the like in contact with the human body for a long time. Various methods have been proposed for blocking such electric waves.

In general, the magnetic field can suppress the occurrence of the first and second columns in the inner and outer sides in the opposite direction such that current flows in the opposite directions. By the way, in the case of an electric field, the shielding is constructed outside and grounded mainly.

However, in the case of such an electric field leakage preventing structure, since the heat wire diameter must be within 3.5 mm due to the structure of the electrothermal bedding, in order to provide an insulating layer between the outer second heater coil and the outer shield, the thickness is inevitably reduced. In this case, there is a problem that a short occurs or melts easily at a high temperature.

Therefore, there is a need for a configuration that can effectively prevent the leakage of the electric field without having to provide such a shield in a structure insulated from the second heater coil.

The present invention utilizes an aluminum plate and an aluminum film to reduce the resistance applied to the second heating wire, thereby lowering the average voltage applied to the rear end of the second heating wire to 10 V or less, thereby providing a heating wire to remove the electric field. For the purpose of

In addition, the present invention uses a flat non-heating heating wire, widening the winding range of the second non-heating heating wire, reducing the leakage of the electric field generated in the first heating wire, aluminum plate, aluminum on the second non-heating heating wire It is an object of the present invention to provide a heating line that is completely sealed by being in wider contact with the film, thereby improving electric field removal performance.

The construction of the present invention for achieving the above object, in the heating wire, in order to block the electric field generated in the second heating wire itself, and the electric field of the first heating wire leaked between the second heating wire gap, to increase the surface area of the second heating wire A heating wire for blocking an electric field by lowering a potential difference by lowering a resistance per unit length of a second heating wire, the heating wire comprising: a first heating wire connected to one terminal of a power source; An inner coating covering the outer side of the first heating wire; A second heating wire surrounding an outer side of the inner coating and having one end connected to the other terminal of the power source; And an outer coating covering and covering the outer side of the second heating wire, wherein the aluminum plate is wrapped while being in contact with the second heating wire between the outer side of the second heating wire and the inner side of the outer coating. It provides a resistance reduced electric field cut-off heating wire per unit length characterized in that the resistance per 1m of the heating wire and the aluminum plate composite is 0.5Ω or less.

In addition, a heating wire for lowering the resistance per unit length to cut off the electric field, comprising: a first heating wire connected to either terminal of the power source; An inner coating covering the outer side of the first heating wire; A second heating wire surrounding an outer side of the inner coating and having one end connected to the other terminal of the power source; And an outer coating covering the outer side of the second heating wire and covering the outer side of the second heating wire, wherein an aluminum thin film layer is provided on one side and a film layer is formed on the outer surface of the second heating wire. The film is wrapped so that the aluminum thin film layer and the second heating wire is wrapped in contact, so that the resistance per unit length of the second heating wire and the aluminum film composite is 0.5Ω or less, characterized in that the resistance reduction electric field blocking heating wire per unit length To provide.

According to the control of the controller of the temperature controller, the heat generation period and the non-heating period are alternately set so that the current is supplied to the first heating wire or the second heating wire for each cycle, and the heating is controlled. A high heating current is supplied to the second heating wire, and the second heating wire is configured to supply a relatively low non-heating current during the non-heating cycle.

The second heating wire is composed of two conductive wires, and is wound around the outer coating in units of the two conductive wires.

The second heating wire is a rolled lead wire having a flat cross section having a flat contact surface.

The second heating wire is characterized by consisting of copper.

The aluminum plate is formed in a tubular shape surrounding the outside of the second heating wire through a forming jig.

The aluminum film is formed in a tubular shape surrounding the outside of the second heating wire through a forming jig.

The present invention has an effect that the shield, such as aluminum plate, aluminum film in contact with the heating wire, completely shields the electric field generated from the heating wire so as not to affect the human body.

In addition, the present invention has the effect of having the electric field shielding configuration in the heating wire in a simple process and configuration.

1 is a view showing a heating wire of the present invention, Figure 2 is a view showing a connection relationship of the heating wire of the present invention.
3 is a diagram showing a connection relationship between the heating wire of the present invention.
4 is a view for explaining a cross section of the second heating wire of the present invention.
5 is a view for explaining the aluminum film of the present invention.
6 and 7 are views showing a heating line provided with an aluminum film of the present invention.
8 is a view showing a process of forming an aluminum plate, an aluminum film of the present invention.
9 is a view showing a cross section of the heating line of the present invention.

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

Korea Electro-Mechanics Testing Institute is providing EMF certification for electromagnetic field that meets the standard of electromagnetic field. In this regard, the human body protection standard is 10V / m between the heating wire surface and ground. . In other words, when the heating wire surface is subjected to an average voltage of 10 V or less on average, it is treated as satisfying the electric field leakage safety certification condition.

In order to satisfy this, the resistance of the heating wire should be dropped, and in the specification of electric sheet, electric yoke, etc., which is usually about 30-50 m, the resistance should be 0.5 Ω or less per 1 m. In order to reduce the resistance, the cross section of the heating wire must be increased or a material having a low resistance must be selected. In the present invention, an aluminum plate and an aluminum film, which were previously treated as shields, were directly contacted with the second heating wire on the outside to increase the energization cross section. This has the effect of reducing the resistance per unit length.

1 is a view showing a heating wire of the present invention, Figure 2 is a view showing a connection relationship of the heating wire of the present invention, Figure 3 is a diagram showing a connection relationship of the heating wire of the present invention. 1 to 3, a bundle of the ventricle 1 made of a synthetic resin material such as polyester is provided at the center thereof, and the first heating wire 10 is wound spirally on the outside thereof. An outer coating 20 for insulation is provided outside the first heating wire 10 and the ventricle 1, and the inner coating 20 may use an insulating material or a nylon series.

The second heating wire 30 is wound spirally on the outside of the inner coating 20, the second heating wire 30 is to wound two (31) (32) or a pair in a set side by side, in some cases May be a set of three or more. At this time, when the second heating wire 30 is used for copper, it may also be sufficient as one second heating wire 30.

On the outside of the second heating wire 30, the second coating and the shield provided on the outside of the conventional heating is removed, and the aluminum heating plate 40 is wrapped in direct contact with the second heating wire 30. The outer coating 50 is molded. Reference numeral 2 is a thermostat.

At this time, the second heating wire 30 should be applied with a voltage of 10 V or less at the position of B on the basis of being grounded to the ground (G). Should be. In other words, the resistance applied to A at the position between A1-A2 should be 0.5Ω / m.

In order to lower the resistance as described above, the second heating wire 30 is wound on the aluminum plate 40 by direct contact, and energized through a large area of 31, 32, and 40, as shown in FIG. Resistance decreases.

In addition, the double-wired heating wire, one cycle of the alternating current to provide a heating current, the other cycle to provide a temperature measurement current in the opposite direction, the high current of the heating cycle to heat through the inner first heating wire 10, and Only the low current for temperature measurement flows through the second heating wire 30 so that the voltage value applied to the second heating wire 30 is lowered. That is, the second heating wire 30 is composed of a non-heating heating wire.

4 is a view for explaining a cross section of the second heating wire of the present invention. Referring to FIG. 4, the second heating wire 30 does not use a circular lead wire as in (a) in order to expand the contact cross-sectional area with the aluminum plate 40, and is rolled flat as in (b) to have a top and bottom surface. Lead wires having planar contact surfaces 31a and 31b are used. As a result, the electric field leakage prevention effect is improved, the outer diameter of the entire heating wire is reduced, and the contact surface with the aluminum plate 40 is also expanded.

5 is a view for explaining the aluminum film of the present invention. Referring to FIG. 5, instead of the aluminum plate 50, a double structure aluminum film 60 may be used. The aluminum film 60 is provided with a thin film layer 62 composed of an aluminum thin film on one surface thereof, and a back surface attached thereto is provided with a synthetic resin and a PE insulating film layer 64.

6 and 7 are views showing a heating line provided with an aluminum film of the present invention. 6 and 7, the aluminum film 60 is disposed so that the aluminum thin film layer 62 is formed so as to face the second heating wire 30 on the inner side, and the film layer 64 is exposed to the outer side. . As shown in FIG. 7, the second heating wires 31 and 32 having the planar contact surface and the aluminum thin film layer 62 of the aluminum film 60 are in contact with each other to maintain a low resistance, thereby lowering the voltage per unit length. Ensure that the criteria for electric field interruption are met.

8 is a view showing a process of forming an aluminum plate, an aluminum film of the present invention. Referring to FIG. 8, the aluminum plate and the aluminum films 40 and 60 are wound along the traveling direction of the extruder in which the heating wire is manufactured, and wound around the second heating wire 30 through the forming jig 70. . The planar aluminum plate and the aluminum films 40 and 60 are advanced together while being spaced apart along the second heating wire 30 wound around the inner coating 20, and then the forming jig 70 having an outer shape wound like a funnel. Retracted inwardly along the), when passing through it is disposed outside the second heating wire 30 in a state of being wound in a long tubular shape.

At this time, the width of the aluminum plate, the aluminum film (40, 60) is wider than the circumference of the inner coating 20 and the second heating wire 30, so that when the final form, the remaining portion (40a, 60a) as shown in (c) ) May be overlapped with each other. The forming jig 70 is preferably installed at the inlet of the PVC outer coating 50 extruder, so that the aluminum plate is formed at the same time as the PVC extrusion.

9 is a view showing a cross section of the heating line of the present invention. Referring to FIG. 9, the final heating line has a second heating wire 30, an aluminum plate and an aluminum film 40, 60 on the outside thereof, and is electrically energized with each other in a composite as shown in the drawing. This decreases, falling below 0.5 Ω per meter. Accordingly, the voltage of the second heating wire is measured at 10 V / m or less, thereby satisfying the electric field authentication condition.

On the other hand, the present invention is not limited to the above-described typical preferred embodiment, it can be carried out in various ways without departing from the gist of the present invention in various ways to improve, change, replace or add to the common knowledge in the art Anyone who has this can easily understand it. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended claims below, the technical concept should also be regarded as belonging to the present invention.

10: first heating wire 20: inner coating
30: second heating wire 40: aluminum plate
50: outer coating 60: aluminum film
70: forming jig

Claims (8)

In the heating wire to cut off the electric field by lowering the resistance per unit length,
A first heating wire connected to either terminal of the power supply;
An inner coating covering the outer side of the first heating wire;
A second heating wire surrounding an outer side of the inner coating and having one end connected to the other terminal of the power source; And
And an outer coating covering and covering the outer side of the second heating wire.
An aluminum plate is wrapped between the outer side of the second heating wire and the inner side of the outer coating while being in contact with the second heating wire, so that the resistance per 1 m of the second heating wire and the aluminum plate composite is 0.5 Ω or less. The electric field blocking heating wire, which decreases the resistance per unit length.
In the heating wire to cut off the electric field by lowering the resistance per unit length,
A first heating wire connected to either terminal of the power supply;
An inner coating covering the outer side of the first heating wire;
A second heating wire surrounding an outer side of the inner coating and having one end connected to the other terminal of the power source; And
And an outer coating covering and covering the outer side of the second heating wire.
Between the outer side of the second heating wire and the inner side of the outer coating, one surface is provided with an aluminum thin film layer and the outer surface is formed of a film layer; the aluminum thin film layer and the second heating wire to be wrapped in contact with the second, Reduction of electric field cut-off heating wire per unit length, characterized in that the resistance per 1m of the heating wire and the aluminum film composite is 0.5Ω or less.
3. The method according to claim 1 or 2,
According to the control of the controller of the temperature controller, the heating cycle and the non-heating cycle is alternately set so that the current is supplied to the first heating wire or the second heating wire for each cycle, and the heating is controlled.
The first heating wire is to supply a high heating current during the heating cycle,
The second heating wire is a resistance reducing electric field cut-off heating wire per unit length such that a relatively low non-heating current is supplied during a non-heating cycle.
3. The method according to claim 1 or 2,
The second heating wire is composed of two conductive wires,
A resistance reducing electric field cut-off heating line per unit length, characterized in that the coil is wound on the outer coating in units of the two conductors.
3. The method according to claim 1 or 2,
And the second heating wire is a flat lead-shaped rolled lead wire having a flat contact surface.
The method of claim 5, wherein
The second heating wire is a resistance reducing electric field blocking heating wire per unit length, characterized in that consisting of copper.
The method of claim 1,
The aluminum plate is formed in a tubular shape surrounding the outside of the second heating wire through a forming jig, resistance reduction electric field cut-off heating wire per unit length.
The method of claim 2,
The aluminum film is formed through a forming jig, the outer periphery of the second heating wire is formed in a tubular shape, resistance reduction electric field blocking heating wire per unit length, characterized in that the.

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