KR20090112411A - Electric warm pipe boiler - Google Patents

Abstract

PURPOSE: An electric heat pipe boiler is provided to install regardless of size of an installation plate and to increase thermal efficiency. CONSTITUTION: Two strands of heating wires have a protective tube as a housing. The protective tube is inserted in an impact resistance tube. The impact resistance tube is inserted in a metal pipe. A heat pipe(100) is consisting of the metal pipe in which the air layer is formed between the impact resistance tubes. A socket(150) is connected to one end of the heat pipe and connects heating wire and a power source cable(201).

Description

Electric warm pipe boiler

The present invention relates to an electric heating tube boiler for heating the room by electricity embedded in the floor, in particular, the configuration is simple, easy to install, excellent thermal efficiency to save heating costs, easy to maintain the electric heating tube boiler It is about.

In general, the heating of indoors inhabited by people embeds hot water pipes in which hot water flows on the floor for a long time, and heats the heating water with heat generated by burning fossil fuels such as coal or oil so that the heating water flows in the hot water pipes. Although configured to heat the room, the conventional method as described above takes a lot of heating costs, there is a problem that takes a long time until the temperature of the floor of the room rises after the boiler operation.

In order to solve the above problems, in recent years, an electric heating tube boiler is installed in which a heating wire is inserted into a floor of an indoor floor, and a heating wire is heated by supplying power to the heating wire inside the pipe to heat the room. It is operating.

The electric heat tube boiler of the above configuration has a merit that the facility cost is low and construction is easy because it does not need a boiler for burning fossil fuel. However, since a single wire of the heating wire is interposed inside the pipe, and the beginning of the pipe and the end of the pipe must be connected to the controller and the electric wire for a long time, construction is inconvenient and there is a risk of safety accident due to breakage of the electric wire. .

In addition, in the past, the electricity was spotlighted as a cheap heating energy, but now the heating cost is doubled according to the amount of electricity used according to the progressive use of electricity, an electric heating tube boiler with better heating efficiency is required.

The present invention has been made to solve the above problems, can be easily installed by the general user without electrical knowledge, can be easily installed regardless of the construction site and construction area, the heat efficiency is excellent heating power consumption It is an object of the present invention to provide an electric heat tube boiler which is low in cost and easy to maintain.

In order to achieve the above object, an embodiment of the present invention is an electric heating tube boiler which is heated by the heat of the heating wire inside the pipe, the protection tube is formed of two strands of the heating wire and the inner tube, the inner tube shock resistance A heat pipe including a tube and the inner shock tube interposed therebetween, the metal pipe having an air layer formed between the metal pipe and the inner shock tube;

A socket fastened to one end of the heat pipe and electrically connecting the heating wire and a power cable; Is coupled to the other end of the heat pipe is configured to include an end socket for electrically connecting the two stranded heating wire in the heat pipe.

In order to achieve the above object, another embodiment of the present invention is an electric heating tube boiler that is heated by the heat of the heating wire inside the heat pipe, the heating tube of the two strands and the protective tube formed of the outer shell, the protective tube is A heat pipe cut into a predetermined length by being formed of an inner shock tube having a heating wire formed therein and an inner shock tube interposed therebetween, the metal pipe having an air layer formed between the metal pipe and the inner shock tube;

A connection cable fastened to an end of each of the heat pipes and having connection holes formed at both sides to electrically connect the heating wires inside the heat pipes; A socket connected to one end of the electrically connected heat pipe to electrically connect the heating wire and the power cable; Is coupled to the other end of the heat pipe is configured to include an end socket for electrically connecting the two stranded heating wire in the heat pipe.

At this time, it further comprises a metal shield formed inside the shock tube.

In addition, the metal pipe further comprises a heat transfer coating applied to the inner surface.

In addition, a terminal is formed in the socket and the end socket, and terminals connected to the terminals of the socket and the end socket are formed at both ends of the heating wire.

Electric heating tube boiler according to the present invention can be easily installed by the general user without electrical knowledge, can be easily installed regardless of the construction site and construction area, excellent heat efficiency, less heating power consumption, maintenance Is simple.

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

1 is a cross-sectional view of a heat pipe according to the present invention, Figure 2 is a state diagram used in accordance with an embodiment of the present invention, Figure 3 is a cross-sectional view showing a fastening structure of the socket and the heat pipe, Figure 4 is an end socket and heat Figure 5 is a cross-sectional view showing a fastening structure of the pipe, Figure 5 is a cross-sectional view of a state in which the electric heat tube boiler of the present invention is installed on the floor, Figure 6 is a state diagram used according to another embodiment of the present invention.

As shown in FIG. 2, the electric heat tube boiler according to the present invention includes a heat pipe 100 in which the heating wire 101 is interpolated and generates heat, a controller 200 for controlling the heat pipe 100, and the heat pipe ( It is composed of a socket 150 is fastened to one end of the 100 to supply electricity to the heat pipe 100, and the end socket 160 is fastened to the other end of the heat pipe (100).

First, the structure of the heat pipe used for this invention is demonstrated.

As shown in FIG. 1, in the heat pipe 100 according to the present invention, a pair of heating wires 101 having a protective tube 102 formed as an outer shell are interpolated in the inner shock tube 104.

The heating wire 101 is a heating wire 101 generally used as a resistor that generates heat when power is applied, and the protection tube 102 is a pair of power wires 101 interpolated in the shock tube 104. This is to prevent the electrical short circuit.

In addition, the protective tube 102 and the impact tube 104 serves to prevent the heating wire 101 from bending during the forming process of bending the heat pipe 100 for construction, and the protective tube 102 and The inner shock tube 104 is an outer shell that directly or indirectly protects the heating wire 101, and is preferably formed of a silicon material that is resistant to heat and well withstands external shocks.

At this time, it is preferable to further configure the metal shield 103 between the protection tube 102, the inner shock tube 104 and the heating wire 101 is inserted. The shield 103 is formed by continuously forming copper like a thread, plating nickel on the surface thereof, and then weaving it like a fabric, and shielding the shield 103 between the impact tube 104 and the protective tube 102 as described above. When configured, the shield 103 blocks the electromagnetic wave generated from the heating wire during the electricity supply, thereby preventing the electromagnetic wave harmful to the human body from radiating to the outside.

In addition, the shield 103 of the metallic material quickly absorbs heat generated from the heating wire 101 and transfers the heat to the shock tube 104 to improve thermal conductivity so that the room is quickly heated.

As described above, the heat pipe 100 is formed by inserting the inner shock tube 104 having the pair of heating wires 101 formed therein into the metal pipe 107, wherein the metal pipe 107 and the shock tube 104 are formed. By forming the air layer 105 between the), the heat generated from the heating wire 101 is accumulated in the air layer 105 to prevent the heat pipe 100 is quickly cooled when the power is cut off, and the air layer 105 at the time of energization Since heat is accumulated in the heat sink, the heat pipe 100 is quickly heated.

The metal pipe 107 is preferably to use a non-ferrous metal in order to prevent corrosion.

It is preferable that the distance between the air layer 105, that is, the impact tube 104 and the metal pipe 107 is 1 mm. If the distance between the impact tube 104 and the metal pipe 107 is less than 1 mm, If the cooling rate is high at the time of power cut and the distance between the impact tube 104 and the metal pipe 107 is greater than 1 mm, it is because the temperature rising speed of the room is slow.

In addition, it is preferable to apply a heat transfer paint 106 to the inner surface of the metal pipe 107. The heat transfer paint 106 is to quickly absorb the heat accumulated in the impact tube 104 to be transferred to the metal pipe 107, and is applied by mixing graphite, germanium stone or loess with a paint having excellent adhesion.

As described above, the heat transfer paint 106 is cement mortar during the construction of the heat pipe 100 in the cold winter, and the inside of the heat pipe 100 is warm when electricity is supplied, and condensation occurs because the surface temperature of the heat pipe 100 is low. The heat transfer paint 106 suppresses the condensation as described above because of the excellent heat transfer rate.

An embodiment of the present invention using the heat pipe 100 configured as described above will be described.

As shown in FIG. 5, after the heat insulator 20 is laid on the upper portion of the foundation concrete 10 and the PVC vinyl 30 is placed on the heat insulator 20, the top of the PVC vinyl 30 is attached to the heat insulator 20. Install the wire mesh 50 in the form of water, the heat pipe 100 is bent and formed in the form of pipes by bending the heat pipe 100 on the mesh-shaped wire mesh 50, the wire pipe 50 to the wire 60 (50) Tied and fixed), the gravel 40 is filled between the heat pipes 100, and the mortar 70 is applied to the upper portion to be constructed.

In addition, the controller 200 controlling the heat pipe 100 has a socket 150 connected to the power cable 201 of the controller 200 at one end of the heat pipe 100 as shown in FIG. 3. Tighten and fasten.

The socket 150 has a pair of terminals 151 connected to the power supply line 201 of the controller 200 therein, so that the terminal 108 is connected to the heating wire 101 inside the heat pipe 100. And the terminal 151 of the socket 150 are electrically coupled to each other so that electricity is supplied to the heating wire 101.

And, as shown in Figure 4 by the end socket 160 is fastened to the other end of the heat pipe 100, so that the two heating wire 101 inserted into the heat pipe 100 is energized. As shown in FIG. 4, the end socket 160 has a terminal 151 coupled to the terminal 108 of the heating wire 101, and the terminal 151 of the end socket 160 is electrically connected thereto. Therefore, when the end socket 160 is fastened to the heat pipe 100, the two heating wires 101 are energized to generate heat when power is applied.

That is, one embodiment of the present invention shown in Figure 2 is bent to form the heat pipe 100 to fit the shape and size of the floor and installed on the bottom, respectively at the beginning and end of the heat pipe 100 By fastening the socket 150 and the end socket 160 can be easily installed.

In addition, the heat pipe 101 is composed of two strands of heat inside the heat pipe 100 is superior in heat generation compared to the conventional heat pipe is excellent thermal efficiency.

6 is a use state diagram according to another embodiment according to the present invention.

As shown in FIG. 6, another embodiment of the present invention cuts and forms a plurality of heat pipes 100a having the configuration shown in FIG. 1, and heats the cut heat pipes 100a having a predetermined length. The heat pipe 100a is installed on the bottom of the necessary place to maintain a constant interval.

And, as shown in Figure 6 so that the internal heating wire 101 of the heat pipe (100a) installed on the floor while maintaining the predetermined interval is connected to the connector 171 formed on both sides of the connecting cable 170 Insert and fasten to the end of the heat pipe (100a) provided at regular intervals.

Then, the socket 150 connected to the power cable 201 of the controller 200 is fastened to one end of the heat pipe 100a electrically connected through the connection cable 170, and through the connection cable 170. By fastening the end socket 160 to the other end of the electrically connected heat pipe 100a so that the two stranded heating wires 101 inside the heat pipe 100a are energized with each other, the electric heat tube boiler according to another embodiment of the present invention It is composed.

Another embodiment of the present invention configured as described above is configured to connect and fasten the heat pipe 100a with a connection cable 170 after the heat pipe 100a of a predetermined length is continuously installed at a predetermined interval. It is simple and maintenance is very easy because only the broken part needs to be replaced.

In the above, the electric heat tube boiler which concerns on this invention was demonstrated. The technical configuration of the present invention will be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the appended claims rather than the foregoing description, and the meanings of the claims and All changes or modifications derived from the scope and equivalent concepts thereof should be construed as being included in the scope of the present invention.

1 is a cross-sectional view of a heat pipe according to the present invention.

2 is a use state according to an embodiment of the present invention.

Figure 3 is a cross-sectional view showing a fastening structure of the socket and the heat pipe.

Figure 4 is a cross-sectional view showing a fastening structure of the end socket and the heat pipe.

5 is a cross-sectional view of the electric heat pipe boiler of the present invention installed on the floor.

Figure 6 is a use state according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: foundation concrete

20: insulation

30: PVC vinyl

40: gravel

50: wire mesh

60: string

70: mortar

100: heat pipe

100a: heat pipe

101: heating wire

102: protective tube

103: shield

104: shock tube

105: air layer

106: heat transfer paint

107 metal pipe

108: terminal

150: socket

151: terminal

160: end socket

170: connecting cable

171: connector

200: controller

201: power cable

202: sensor cable

Claims (5)

In the electric heating tube boiler which is heated by the heat of the heating wire inside the pipe, The protection tube 102 has two outer heating wires 101 formed with an outer shell, the inner shock tube 104 in which the protection tube 102 is interpolated, and the inner shock tube 104 are interpolated, and the metal pipe 107 and A heat pipe (100) consisting of a metal pipe (107) having an air layer (105) formed between the impact tube (104); A socket 150 fastened to one end of the heat pipe 100 to electrically connect the heating wire 101 and the power cable 201; And an end socket (160) connected to the other end of the heat pipe (100) to electrically connect two stranded heating wires (101) in the heat pipe (100). In the electric heating tube boiler that is heated by the heat of the heating wire inside the heat pipe, Two inner heating wires 101 having a protective tube 102 formed of an outer shell, an inner shock tube 104 having an inner heating tube 101 having the protective tube 102 interpolated therebetween, and the inner shock tube 104 interposed therebetween. A heat pipe (100) formed of a metal pipe (107) having an air layer (105) formed between the metal pipe (107) and the impact tube (104) and cut to a predetermined length; A connection cable 170 coupled to an end of each of the heat pipes 100 and having a connector 171 formed at both sides to electrically connect the heating wires 101 inside the heat pipes 100 in series; A socket 150 coupled to one end of the electrically connected heat pipe 100 to electrically connect the heating wire 101 and the power cable 201; And an end socket (160) coupled to the other end of the heat pipe (100) to electrically connect two stranded heating wires (201) in the heat pipe (100). The method according to claim 1 or 2, Electric heat tube boiler, characterized in that further comprises a metal shield (103) formed inside the shock tube (104). The method according to claim 1 or 2, The electric heat pipe boiler, characterized in that it further comprises a heat transfer paint (106) applied to the inner surface of the metal pipe (107). The method according to claim 1 or 2, Terminals 151 are formed at the socket 150 and the end socket 160, and terminals 108 are connected to terminals 151 of the socket 150 and the end socket 160 at both ends of the heating wire 101. Electric heat tube boiler, characterized in that formed.

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