KR101612156B1 - The heat cable that adjustment of the calorific value is possible - Google Patents

Abstract

A heating cable 100 capable of adjusting a calorific value according to the present invention includes a heating wire 110 for generating electrical resistance heat by electrical conduction as a wire rod and a copper wire 120 arranged side by side on both sides of the heating wire 110 And a cover 130 covering the hot wire 110 and the copper wire 120 together.
Accordingly, electrical conduction can be achieved by the plurality of sleeves 150 connecting the hot wire 110 and the copper wire 120, and the calorific value can be adjusted by the pitch of the sleeve 150.

Description

[0001] The present invention relates to a heating cable capable of adjusting a calorific value,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating cable capable of adjusting a calorific value, and more particularly, to a heating cable capable of adjusting a calorific value by adjusting a pitch of a sleeve connecting a copper wire and a hot wire.

1 is a perspective view showing a heating cable according to the background art.

Carbon fiber, nichrome wire, and kanthal are used as the heat ray 10 that generates resistance heat by electric conduction.

The heat ray 10 is covered with the heat-resistant resin 20, and may be arranged side by side in parallel as in the prior art document, or may be composed of a single wire.

Since the hot wires 10 are connected in series, a positive power source is connected to one end portion and a negative power source is connected to the other end portion, resistance heat can be generated through the hot wire 10. The series connection means that a plurality of heat wires 10 are connected to each other at the end portions thereof and are configured to be long in the longitudinal direction.

Such a heating cable 1 is used for indoor heating for building use, as a heating means inside a vinyl house for agricultural use, and as a general household appliance, and is applied to various fields such as electric wires and electric panels.

(Document 1) Korean Patent Publication No. 10-2012-0063831 (June 18, 2012)

According to the background art, since the calorific value of the heat ray is inversely proportional to the length and is proportional to the thickness, when the length is uniform, the calorific value can be controlled by manufacturing various thicknesses. Or when the thickness is made uniform, the heating amount can be adjusted because it is manufactured in various lengths.

For example, if a heating wire having a diameter of 3 mm and a length of 20 m can generate a heating value of 100 kcal, it is possible to form the wire diameter as 3 mm or more in order to generate a heating value of 200 kcal in the same length.

Alternatively, in order to increase the heating value in a state that the wire diameter is 3 mm and the wire diameter is uniform in the heating wire of 20 m, it is possible to reduce the length of the heating wire.

However, in general, there is a necessity to adjust the lengths in various ways by connecting the heat lines in series. Therefore, it is inevitably necessary to adjust the calorific value as the thickness of the heat ray, which is the diameter of the heat ray.

Therefore, in the production site, the heating cable with built-in heat wire is produced in a prescribed length, and since the wire diameter of the heat wire is variously produced in order to generate various heat amounts, the production facility must be provided separately according to the wire diameter. Therefore, there is a problem in that the investment cost is increased. As the length is increased, the calorific value is decreased. Therefore, in order to increase the thermal efficiency, the thickness of the heat ray must be increased so that the production cost is increased, the weight is increased, .

Further, since the constructor can not start the construction immediately after having provided the heating cable in advance, there is a problem that it is difficult to perform the construction promptly. The reason for this is that you have to adjust the amount of heat according to the demand of the customer, so you have to order the heat ray of the sunlight that generates the heat value after receiving the order. That is, the heating cable previously provided can not match the desired heating value of the customer.

And a tubular reinforcing skin to which the covering material is fitted so as to cover the covering material.

A heating cable capable of adjusting the calorific power according to the present invention includes a heating wire for generating electric resistance heat by electrical conduction as a wire member, a copper wire arranged in parallel to both sides of the heating wire, and a covering member for covering the heating wire and the copper wire together .

The protrusions protrude outward from the covering material and are disposed on one side of the copper wire in order to distinguish the copper wires.

And a C-shaped sleeve which is separated from the covering material and is used for connecting the copper wire on one side and the hot wire, the conductor being formed to be able to receive and press the copper wire on one side of the copper wire and the hot wire. do.

And a finishing material for covering the sleeve in a state where the sleeve is separated from the covering material and is used to connect the copper wire on one side and the hot wire while the sleeve receives the copper wire and the hot wire on one side, .

A cut-out portion for removing a part of the covering material to expose one or both of the copper wire and the hot wire of the copper wire, a C-type sleeve pressed to receive the one-side copper wire and the hot wire, And a finishing material which is a non-conductor attached to the cover to cover the sleeve. The cut-out portion is formed by alternately arranging one side of the copper wire and the exposed hot wire, and the other side of the copper wire and the hot wire exposed.

The heating cable capable of adjusting the calorific power according to the present invention has the effect of freely adjusting the heat generation amount since the pitch for mounting the sleeve is adjusted while the wire diameter of the heating wire is constantly produced. Therefore, since it is not necessary to produce the heat ray separately for each thickness, it is possible to reduce the investment cost of the production facility less than the background technology, and it is not necessary to increase the diameter to increase the heat generation amount. Therefore, the production cost can be reduced and the weight and volume can be reduced as compared with the background technology, so that the transportation is easy.

In addition, since the manufacturer can adjust the amount of heat generation required by the customer by mounting the sleeve immediately after the installation request, if there is a request for construction, the construction worker can start construction immediately upon ordering.

As another embodiment of the present invention, when the sleeve and the finishing material are preliminarily formed, the pitch of the sleeve is adjusted after manufacturing a heat wire of a single wire diameter, without forming various heat wire of different diameters according to the heating value in the field, There is an effect of reducing the investment cost of the facility for producing various heat ray lines.

1 is a local perspective view showing a heating cable according to the background art;
2 is a sectional view showing a heating cable capable of adjusting a calorific value according to the technique of the present invention.
3 is a local perspective view showing a process in which a sleeve is mounted on a heating cable capable of adjusting a calorific value according to the technique of the present invention.
4 is a local perspective view showing a state in which a sleeve is mounted on a heating cable capable of adjusting a calorific value according to the technique of the present invention.
Fig. 5 is a local perspective view showing a state in which the sleeve is covered with the finishing material in the state of Fig. 4; Fig.
Fig. 6 is a plan view showing a heating cable capable of adjusting a calorific value according to Fig. 5; Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heating cable, and more particularly to a heating cable capable of adjusting a calorific value of the heating cable. 4 is a local perspective view showing a state in which a sleeve is mounted on a heating cable capable of adjusting a calorific value according to the technique of the present invention, Fig. 5 is a local perspective view showing a state in which the sleeve is covered with a finish material in Fig. 5 is a plan view showing a heating cable capable of adjusting a calorific value according to Fig.

The present invention is characterized in that the amount of heat generated by the heat ray 110 can be easily controlled.

To this end, in the present invention, a hot wire 110 for generating electrical resistance heat by electrical conduction as a wire member is constituted. In addition, copper wires 120 arranged in parallel on both sides of the hot wire 110 and capable of applying power can be formed. And a cover 130 covering the hot wire 110 and the copper wire 120 together.

The heat ray 110 may be formed of, for example, carbon fiber, nichrome wire, or kanthal.

The hot wire 110 and the copper wire 120 may be coated in the covering material 130 or may be formed in the covering material 130 in an exposed state without being coated.

The covering material 130 is a non-conductive synthetic resin having heat resistance, and examples thereof include vinyl chloride, synthetic rubber, polyester, epoxy, silicone, and the like. One side of the copper wire 120 is connected to the positive electrode, and the other side is connected to the negative electrode. The protrusions 140 protrude outward from the cover 130 and are disposed on one side of the copper wire 120 among the copper wires 120 to distinguish electrodes connected to the copper wires 120. Preferably, the protrusions 140 are continuously formed in the longitudinal direction, as shown in FIGS.

The copper wire 120 is separated from the covering material 130 and is used to connect the copper wire 120 to the hot wire 110. The copper wire 120 and the hot wire 110, And a C-shaped sleeve 150 formed of a conductor so as to be able to receive and compress the cigarette. The sleeve 150 is preferably formed of copper, which is generally used as a conductive material.

The sleeve 150 is separated from the cover 130 and is used to connect the copper wire 120 to the hot wire 110. The sleeve 150 is connected to the copper wire 120 and the hot wire 110 And a finishing material 160 covering the sleeve 150 in a compressed state. The finishing material 160 is a non-conductive material having excellent heat resistance, and may be made of silicon, for example, and may be made of a tape.

Hereinafter, the use of the present invention will be described.

In the heating cable 100, which can adjust the amount of heat generated, the sleeve 150 and the finishing material 160 are separately formed.

In this state, a plurality of pitches corresponding to the amount of heat output to the covering material 130 are displayed at the time of construction. A portion of the covering material 130 is removed from the pitch point to form a cutout portion 170 in which one or both of the copper wire 120 and the hot wire 110 are exposed. That is, the cut-out portion 170 in which the one-side copper wire 120 and the hot wire 110 are exposed, and the cut-out portion 170 in which the counter copper wire 120 and the hot wire 110 are exposed are alternately arranged. At this time, when the copper wire 120 and the hot wire 110 are covered with the covering material, they are removed and exposed.

After the exposed copper wire 120 and the hot wire 110 are received in the sleeve 150, the sleeve 150 is pressed with a bench or the like to press the copper wire 120 and the hot wire 110.

The sleeve 150 and the copper wire 120 and the hot wire 110 exposed by the finishing material 160 are covered with the covering material 130. When the finishing material 160 is made of silicone, it can be filled in the cut-out portion 170 to be solidified. When the finishing material 160 is a tape, it can be attached to the covering material 130 so that the cut-out portion 170 is covered.

In this state, any one of the copper wires 120 is connected to the positive electrode and the rest is connected to the negative electrode. At this time, the protrusion 140 may be a reference for distinguishing which copper wire 120 is connected to the positive electrode.

Accordingly, current flows from the copper wire 120 connected to the positive electrode to the hot wire 110 and the copper wire 120 connected to the negative electrode, so that the hot wire 110 generates electric resistance heat.

At this time, since each sleeve 150 can obtain the same effect as connecting a plurality of heat wires 110 in parallel, the same amount of heat is generated for each zone (for each pitch). Since the heating value of the heating wire 110 is inversely proportional to the length when the wire diameter is the same, the pitch of the sleeves 150 (the pitch of the cutouts 170) is adjusted, so that the heating value can be easily controlled.

The present invention can be configured such that the heat generator can freely adjust the amount of heat generated by the contractor in the state where the present invention is provided. In another embodiment, the combination of the sleeve (150) and the finish material (160) .

That is, a portion of the covering material 130 is removed to form a cutout portion 170 for exposing one or both of the copper wire 120 and the hot wire 110 among the copper wire 120. A C type sleeve 150 is formed by receiving the one side copper wire 120 and the hot wire 110 so as to be pressed into a conductive material and covers the sleeve 150 to be attached to the covering material 130 And a non-conductive finish 160.

The cutout 170 is formed by alternately arranging the one copper wire 120 and the exposed hot wire 110 and the exposed copper wire 120 and the hot wire 110 alternately.

And a tubular reinforcing skin (U) in which the covering material (130) is fitted to cover the covering material (130). The reinforcing skin (U) has rigidity and functions to withstand external pressures. For example, the reinforcing skin (U) may be woven with metal wires such as stainless steel. Therefore, when installed on the lower part of the road surface for the purpose of snow removal, it can be prevented from being damaged by the weight of the upper asphalt or concrete, and the damage of the covering material 110 by the sharp object or frame can be prevented.

100: Heating cable with adjustable heating value 110: Heat line
120: Copper wire 130: Cover material
140: projection 150: sleeve
160: Finishing material 170:
U: reinforcement skin

Claims (6)

A hot wire 110 for generating electric resistance heat by electrical conduction as a wire rod,
A copper wire 120 arranged in parallel on both sides of the hot wire 110,
And a covering material (130) covering the hot wire (110) and the copper wire (120) together;
And protrusions 140 protruding outward from the cover 130 to be connected to one of the copper lines 120 and disposed on one side of the copper line 120 among the copper lines 120. [ Heating cable with adjustable heating value. delete The method according to claim 1,
Is separated from the covering material (130) and is used to connect the copper wire (120) to the hot wire (110)
And a C-type sleeve (150) formed to accommodate the copper wire (120) and the hot wire (110) on one side of the copper wire (120) and capable of compressing the heating wire (110). The method of claim 3,
Is separated from the covering material (130) and is used to connect the copper wire (120) to the hot wire (110)
And a finishing material 160 covering the sleeve 150 in a state where the sleeve 150 receives the copper wire 120 and the hot wire 110 and is compressed. Possible heating cables. The method according to claim 1,
A cutout 170 for removing a part of the cover 130 to expose one or both of the copper wire 120 and the hot wire 110 among the copper wire 120,
A C-type sleeve 150 formed of a conductor and received by the one side copper wire 120 and the hot wire 110,
And a finishing material 160 covering the sleeve 150 and being a non-conductor attached to the covering material 130,
The incision 170 is formed by alternately arranging the one copper wire 120 and the exposed hot wire 110 and the exposed copper wire 120 and the hot wire 110 alternately. Heating cable. 6. The method of claim 5,
And a tubular reinforcing skin (U) in which the covering material (130) is fitted so that the covering material (130) is covered.

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