KR101081344B1 - layed type electric heat appratus and manufacture method therefor - Google Patents

Abstract

The present invention relates to a buried heat transfer device that prevents the heating rods generated by the power source from being corroded in soil mixed with base and sulfuric acid when the buried heat transfer device is installed on the ground, such as a road surface.

The buried type heating apparatus of the present invention for this purpose, a pair of wires are arranged spaced apart a predetermined distance in the horizontal direction, a plurality of wires are arranged at regular intervals in a vertical direction between the pair of wires, consisting of a tubular heating wire inside The heating terminal is disposed in the longitudinal direction, and a connecting terminal is connected to both ends of the heating wire, respectively, and is connected to the electric wire. The shrinkage is applied to the heating rod to protect the heating rod from salt, sulfuric acid and the like, and the injection molding in the T-shape to cover the connection area by the top portion (D1) and valleys (D2) To be formed repeatedly, the molded part is made of a resin of Br-Epoxy flame retardant material, so that the upper and lower surfaces of the molded part is made of a flat Generated T-shape includes a sealing cap, and reinforce said molding portion to form a rib in the vertical direction in the region in which the molded parts of the horizontal portion and a vertical portion connected.

The present invention can be used permanently by wrapping the heating rod with a heat shrink tube so that corrosion does not occur when embedded in the road surface exposed to sulfuric acid, salted soil.

Injection molding, heating rod, sealing cap, bone, ridge

Description

Buried type electric heat appratus and manufacture method therefor}

The present invention relates to a buried heat transfer device, and in particular, a buried heat transfer device for preventing the heating rod generated by the power source in the soil mixed with base, sulfuric acid, etc. when the buried heat transfer device is installed on the ground, such as road surface, etc. It relates to a manufacturing method of the heat transfer device.

In general, the buried heating device serves to heat the floor installed in the school, home, factory, road surface or airport runway surface, it can be divided into heating method using a hot water pipe and heating method using a heat pipe. Installing the buried heat transfer device on the road surface or on the runway surface of the airport prevents snow from accumulating on the road surface during the winter season and prevents the formation of ice on the road surface so as not to freeze rainwater or melted water. It is to prevent.

Among the heating methods, the present invention applies a buried type heat transfer device utilized for a heating method using a heat transfer tube, and the heating rod of the buried heat transfer device is made of a metal material such as aluminum and stainless steel.

1 is a view showing the overall structure of a conventional embedded heating device.

A plurality of plugs (P) for inputting power, two wires (1) branched from the plug (P), and two wires (1) connected in parallel and spaced apart at regular intervals. It consists of two heating rods (2).

The connecting portion of the wire 1 and the heating rod 2 is sealed by the T-shaped sealing cap (4). The two strands of wires 1 are made of a conductor 1a and an outer shell 1b surrounding the conductor 1a so that a current flows, and the heat generating rod 2 is a heat generating element 2a and the heat generating element 2a. It consists of a shell (2b) surrounding the.

The outer shell 1b of the wire is peeled off so that the conductive connector 3 is electrically connected to the exposed conductor 1a and the heating element 2b of the heating rod 2.

And the T-shaped sealing cap (4) is formed in a form that is separated up and down, and coupled to the connecting portion of the wire and the heating rod (1) and the heating rod (2) up and down in a manner of melt bonding using ultrasonic or high frequency Seal the connection between the wire (1) and the heating rod (2).

The heating rod of the buried heat transfer device is made of a metal material such as aluminum, stainless steel, etc., there is a problem in that the corrosion occurs when embedded in the road surface exposed to sulfuric acid, salty soil, shortening the lifespan.

In the case of installing the buried heat transfer device in the volcanic and salty soil, there was a problem that the buried heat transfer device could not be used because it was completely corroded after 3 months.

Disclosure of Invention An object of the present invention is to provide a buried type heat transfer device and a method of manufacturing the heat transfer device that can be used permanently by preventing corrosion when embedded in a road surface exposed to sulfuric acid and salty soil.

The buried heat transfer device of the present invention for achieving the above object is a pair of wires are arranged spaced apart a predetermined distance in the horizontal direction, and a plurality of wires are arranged at regular intervals in a vertical direction between the pair of wires, The heating wire is arranged in the longitudinal direction therein, the connecting terminal is connected to both ends of each of the heating wire is connected to the wire, the heating rod is filled with a heating material in the inside of the tube, the heating rod is inserted into the predetermined temperature It is contracted upon heating and applied to the heating rod to heat-shrink tube for protecting the heating rod from salt, sulfuric acid, etc., and injection molding in a T-shape to cover a portion where the heating rod and the wire are electrically connected. The molded part is to be formed repeatedly the acid (D1) and the bone (D2), the molded part is made of a resin of Br-Epoxy flame retardant material, It includes a T-shaped sealing cap formed so that the upper surface and the lower surface of the pre-formed portion formed in a plane, and the ribs are formed in a vertical direction to the portion where the horizontal portion and the vertical portion is connected to the molded portion to reinforce the strength of the molded portion do.

The heat shrink tube is formed of a polyolefin material, it is characterized in that it is formed to be applied to the heating rod by being contracted by heating to 170 ℃ in a sealed space after being inserted into the heating rod.

Embedded method of manufacturing a heating device of the present invention for achieving the above object,

The heating wire is formed of a stainless steel tube, and the heating wire is disposed in the longitudinal direction, and both ends of the heating wire are connected to the wires, respectively, and a heat shrink tube is inserted into the heating rod filled with the heating material. And then applying a heat shrink tube to the heating rod by shrinking by heating to a predetermined temperature in a closed space,

Arranging a pair of electric wires formed by a conductor through which a current flows and a protective cover surrounding the conductor to insulate the outside from each other by a predetermined distance in a horizontal direction;

Disposing heating rods at regular intervals between the pair of wires in a vertical direction;

Electrically connecting the heating rod and the wire coated with the heat shrink tube;

And forming a molding part by injection molding a portion where the heating rod and the wire are electrically connected.

Both ends of the tube are provided with a stopper to protect the heating wire or the heat transfer material from the inside of the tube from moisture, and the connection point of the wire and the connection terminal is received as a double sleeve terminal, the wire is a (+) wire 21 and It includes a (-) wire 22, each connected to both ends of the heating rod,

The electric wire is such that the sleeve terminal is connected in series to a pair of connection points for connecting with the connection terminal of the heating rod,

The molded part is formed by the acid (D1) and the valley (D2) is repeatedly formed to improve the sealability, characterized in that made of a resin of Br-Epoxy flame retardant material.

The present invention has the advantage that it can be used permanently by preventing the occurrence of corrosion when embedded in the road surface exposed to sulfuric acid, salted soil wrapped around the heating rod with a heat shrink tube.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in more detail with reference to the accompanying drawings in which: FIG. It should be understood, however, that the invention can be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It should be noted that the embodiments of the present invention described below are only for explaining the spirit of the present invention to a person skilled in the art, and a detailed description of known functions and configurations of the present invention which may unnecessarily obscure the gist of the present invention It should be noted that it is omitted.

Figure 2 is a plan view showing the overall structure of the embedded heating device according to the present invention.

3 is a perspective view illustrating main parts of the molding part 30 of FIG. 2;

4 is a plan view illustrating main parts of the molding part 30 of FIG. 2;

5 is a plan sectional view of main parts of the molding part 30 of FIG.

6 is a view showing a state before coupling the shrink tube 18 to the heating rod 10 shown in FIG.

A pair of wires 20 arranged to be spaced apart a predetermined distance in a horizontal direction,

The heating wire 12 is disposed in the vertical direction between the pair of wires 20 and consists of a tubular body 11, and a heating wire 12 is disposed in the longitudinal direction, and both ends of the heating wire 12 are connected to the wires 20, respectively. Is connected to the terminal 13 is installed, the heating rod 10 is filled with the heat transfer material 14 in the inside of the tubular body 11,

A heat shrink tube 18 inserted into the heating rod 10 and contracted when heated to a preset temperature to protect the heating rod 10 from salt, sulfuric acid, and the like;

A molding part 30 which seals the connection part by forming the connection part by injection molding in a T-shape in the state in which the heating rod 10 and the electric wire 20 are electrically connected;

 Rib 33 formed in the vertical direction to reinforce the strength of the molding portion 30 in the portion where the horizontal portion 31 and the vertical portion 32 of the molding portion 30 is connected.

2 to 5 will be described in detail a preferred embodiment of the present invention.

The pair of wires 20 are spaced apart a certain distance in the horizontal direction. The electric wire 20 is formed of a conductor through which a current flows and a protective cover surrounding the conductor for insulation from the outside.

A plurality of heating rods 10 are installed at regular intervals in the vertical direction between the pair of wires 20. The heating rod 10 is formed of a tubular body 11 made of stainless material so that the heating wire 12 is disposed in the longitudinal direction therein, and both ends of the heating wire 12 are connected to the wires 20, respectively ( 13) is installed, the heat transfer material 14 is filled in the inner tube (11).

Both ends of the tubular body 11 are provided with a stopper 15 to protect the heating wire 12 or the heat transfer member 14 from the inside of the tubular body 11 from moisture, and a connection point between the electric wire 20 and the connection terminal 13. It will be received by the double sleeve terminal (16). The wire 20 includes a positive wire 21 and a negative wire 22 and is connected to both ends of the heating rod 10. The wire 20 is formed in a pair to connect with the connection terminal 13 of the heating rod 10, the sleeve terminal 17 is connected in series to the connection point.

After inserting the heat shrink tube 18 into the heating rod 10 as shown in FIG. 6, the heat shrink tube 18 is placed in a heater (not shown), sealed, and heated to a set temperature, for example, 170 ° C., to shrink the heat shrink tube 18. To be applied to the heat generating rod 10. The heat shrink tube 18 is made of a polyolefin material. The polyolefin has excellent resistance to chemicals such as salts, acidic alkaline oils, and various solvents.

The molding part 30 is formed by injection molding the connection part in the state in which the heating rod 10 and the electric wire 20 wrapped by the heat shrink tube 18 are electrically connected as described above. The molded part 30 is to be a T-shaped sealing cap. Molding portion 30 is to be formed by the peak portion (D1) and the valley portion (D2) to improve the sealability. The molded part 30 is made of a resin of Br-Epoxy flame retardant material, and the sealing property is improved by the shrinkage difference of the resin. In other words, the acid portion (D1) is filled with a lot of resin is a lot of shrinkage, bone portion (D2) is a resin filling is less shrinkage is made to improve the sealability. In other words, upon cooling after injection molding of the molding part 30, the shrinkage effect is enhanced by the difference in temperature between the bone part D2 and the ridge part D1, thereby improving the sealing property.

The present invention between the T-shaped sealing cap and the wire 10 and the T-shaped sealing cap and the heating rod 10 by injection molding without using a sealing member such as O-rings or packing in the wire 20 and the heating rod 10 Can be used to reduce manufacturing costs and increase productivity.

The shrinkage of the resin of the Br-Epoxy flame retardant material used in the present invention is most preferably 5/1000, and maximizes the shrinkage effect due to the difference between the transverse axis and the longitudinal shrinkage coefficient. Most preferably, the transverse shrinkage coefficient is 17% and the longitudinal volume coefficient is 43%.

The transverse shrinkage coefficient A = (D1-D2) / D1, it can be calculated by the longitudinal volume coefficient B = 2Rb / 2Ra. (Ra = radius radius, Rb = radius radius)

When the sum of the transverse shrinkage coefficient and the longitudinal volume coefficient is in the range of 50% to 75%, the stability of the resin is best, and the present invention provides the best stability of the resin in the range of 60%. .

The upper and lower surfaces of the molding part 30 are formed in a flat surface, and when the heat transfer device is embedded in the ground, the area contacted with the ground is optimized so that installation (construction) is easy and stability can be maintained.

In addition, the molding part 30 has ribs 33 formed at a portion where the horizontal part 31 and the vertical part 32 are connected to reinforce the strength of the molding part 30 so that a high load on a cold road or the like is severe. When applied, it is possible to prevent deformation or breakage to prevent watertight destruction of the molded part 30 and the electric wire 20 and the molded part 30 and the heat generating rod 10, and to prevent the occurrence of a short circuit.

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1 is a view showing the overall structure of a conventional buried heat transfer device

Figure 2 is a plan view showing the overall structure of the embedded heating device according to the present invention.

3 is a perspective view illustrating main parts of the molding part 30 of FIG. 2;

4 is a plan view illustrating main parts of the molding part 30 of FIG. 2;

5 is a cross-sectional plan view of main parts of the molding part 30 of FIG.

6 is a view showing a state before coupling the shrink tube 18 to the heating rod 10 shown in FIG.

<Brief description of symbols for the main parts of the drawings>

10: heating rod 11: tube

12: heating wire 13: connector

14: heat transfer material 15: stopper

16: dual sleeve terminal 17: sleeve terminal

20: electric wire 30: molding part

31: horizontal part 32: vertical part

33: rib

Claims (3)

In buried heat transfer device, A pair of wires 20 arranged to be spaced apart a predetermined distance in a horizontal direction, A plurality of wires are arranged at regular intervals in the vertical direction between the pair of wires, and the heating wires are arranged in the longitudinal direction inside the pipe 11, and connecting terminals each having both ends of the heating wires connected to the wires are installed. The heating rod 10 is filled with a heat transfer material in the inside of the tubular body 11, A heat shrink tube 18 inserted into the heat generating rod 10 and contracted when heated to a predetermined temperature and applied to the heat generating rod to protect the heat generating rod from salt, sulfuric acid, and the like; An injection molding in a T-shape to cover the connection portion electrically connected between the wire 20 and the heating rod 10, the forming portion 30 is repeatedly formed in the ridge (D1) and valleys (D2). The molding part 30 is made of a resin of Br-Epoxy flame retardant material, and includes a T-shaped sealing cap formed so that the upper and lower surfaces of the molding part 30 are planar. A buried heat transfer device, characterized in that to form a rib in the vertical direction at the portion where the horizontal portion and the vertical portion of the forming portion 30 is connected to reinforce the strength of the forming portion. The method according to claim 1 The heat shrink tube 18 is formed of a polyolefin material, and is inserted into the heat generating rod 10 and is characterized in that it is formed to be applied to the heat generating rod 10 by shrinking by heating to 170 ℃ in a closed space. Buried type heating device. In the buried type heating apparatus manufacturing method, After the heat shrink tube 18 is formed on the outside of the heating rod 10 formed of a stainless steel tube 11 and the heating wire is disposed in the longitudinal direction, and the heat transfer material is filled in the inner tube 11. Applying a heat shrink tube 18 to the heating rod 10 by shrinking by heating to a predetermined temperature in a closed space; Arranging a pair of wires 20 formed of a conductor covering a current flowing through the conductor and a protective cover surrounding the conductor so as to be spaced apart by a predetermined distance in a horizontal direction; Arranging the heating rods 10 at regular intervals between the pair of wires 20 in a vertical direction; Electrically connecting the wires 20 and the heating rods 10, and forming the molding part 30 by injection molding on the electrically connected portions, Both ends of the tubular body 11 are provided with a stopper to protect the heating wire or the heat transfer material inside the tubular body 11 from moisture, and stores the connection point of the wire 20 and the connecting terminal as a double sleeve terminal, the wire Silver includes a (+) wire 21 and a (-) wire 22, each connected to both ends of the heating rod 30, The wire 20 allows the sleeve terminal to be connected in series to a pair of connection points to connect with the connection terminal of the heating rod 10, The shaping portion 30 is formed by the acid (D1) and the valley (D2) is repeatedly formed to improve the sealability, buried heat-transfer device manufacturing method, characterized in that made of a resin of Br-Epoxy flame retardant material.

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