KR20130122864A - Manufacturing method of heater for electric heating system - Google Patents

Abstract

The present invention relates to a method for manufacturing an electric heating pipe that includes a step for preparing a pipe(10), a step for preparing a pipe installation body by successively inserting a U-shaped heating line(20) into the through hole of a first insulating formation body(31) and a second insulating formation body, a step for inserting the pipe installation body into the pipe(10), a step for inserting a silicone cover(40) into one end of the pipe(10), a step for filling the pipe with an insulating material(60), a step for inserting a terminal part(70) into the other end of the pipe(10), a step for reducing the diameter of the pipe(10) by a roller for reducing the diameter of the pipe after the insertion of the pipe installation body, the insertion of the silicone cover(40), the filling of the insulating material(60), and the insertion of the terminal(70) are completed in the pipe(10), and a step for pressuring and fixing the cover(50) to the end of the diameter-reduced pipe(10). [Reference numerals] (AA) Prepare a pipe;(BB) Prepare a pipe installation body;(CC) Insert the pipe installation body into the pipe;(DD) Insert a silicon cover into one end of the pipe;(EE) Fill the pipe with an insulating material;(FF) Insert a terminal part into the other end of the pipe;(GG) Reduce the diameter of the pipe by a roller;(HH) Pressurize and fix the cover to the end of the diameter-reduced pipe

Description

Manufacturing method of electric heating pipes {Manufacturing method of heater for electric heating system}

The present invention relates to a method for manufacturing an electrothermal heating pipe that heats surrounding air or an object using a heater heated by heat generation of a heating wire. The present invention relates to a method of manufacturing an electrothermal heating pipe, which does not leak internal filling insulation during work, and prevents leakage and pipe bursting due to moisture penetration and reduces magnetic field generation during use.

An electrothermal heating pipe is a heating device used to heat a heater heated by heating of a heating wire or an object around it by arranging a heating wire in a pipe, filling an insulator, and applying electricity to the heating wire. Powdered magnesium oxide (MgO, Magnesia) is used.

However, there have been many applications for the electrothermal heating pipe article itself, but the manufacturing method simply inserts an assembly consisting of a pipe, a heating wire, an insulator, and a fixing member into a rotary roller type tube tube so that the tube has a smaller diameter. It stops.

Below we will look at the manufacturing method included in the prior application technology.

Patent No.900193 (electric heater assembly) relates to a heater assembly for an electric ondol in which a pair of heating wires are disposed inside a pipe, and includes a pair of long coil spring shapes so that the pipe and the magnetic field cancel each other out. A hot wire, a fixing member fixed to a hot wire end, and a magnesia filler structure filled in a pipe are disclosed.

There is no direct mention in the above technique of how to manufacture the heater assembly. However, in the proposed configuration, the technique is understood to form a heater assembly by inserting an assembly consisting of a pipe, a heating wire, an insulator, and a fixing member into a rotary roller condenser to conduit to a smaller diameter to form a heater assembly. The magnesia insulator is compressed to discharge the air inside the pipe, which has the effect of sealing the insulator and blocking external water inflow.

However, in the above technique, the fixing member is made of ceramic or heat-resistant plastic. Therefore, in the case of the ceramic material fixing member, there is a problem in that the ceramic is broken in the process of tube shaft leakage of the internal magnesia insulator and also cracks in the ceramic inflow of moisture from the outside during use, the heat-resistant plastic material fixing member In the case that the fixing member presses the heating wire during the shaft tube process, there is a problem that disconnection occurs at both sides of the compressed heating wire as the contracted tension of the heating wire is repeated when the product is used.

In particular, in the above technique, since the hot wire is exposed to the outside of the fixing member which is not filled with the insulator, the hot wire is easily exposed to external moisture, and there is a risk of disconnection due to careless handling during use or in a work process.

In addition, Utility Model No. 314649 (Cartridge Heater) consists of a hollow tube, a pair of heat transfer coils, an insulating filler made of magnesium oxide, a silicone plug inserted into the hollow tube, and the like. The inside of the press or other press mold, and the diameter of the hollow tube is uniformly compressed by using a conventional rotary roller type tube machine, and the air of the hollow tube exits to the outside while the diameter is reduced to maintain the vacuum state. ' I introduce it.

However, in the above technique, the magnetic field is canceled by the pair of heat transfer coils disposed inside the hollow tube, and a silicone stopper is inserted at the end of the hollow tube to seal the internal insulator, but the heating wire is not fixed so that the hot wire is elastic. There is a problem that can not be extended, because the insulation is filled in a state that the heating wire is not supported inside, the heating wire may be twisted or the separation distance may be close, leading to a short circuit accident. In particular, when the heating wire is long, the problem may be more frequent, even in the case of Patent No. 900193 described above.

The present invention has been made to solve such problems,

1. The purpose of this is to maintain the alignment of the heating wires when the insulation is filled by supporting the heating wire inside the pipe and to facilitate the filling of the insulation.

2. Another purpose is to insert a silicone stopper at the end of the pipe to prevent leakage of the insulation during the conduit process.

3. In addition, the purpose is to reduce the risk of electromagnetic waves by disposing the heating wires embedded in the pipe in a U-shape.

According to the present invention, the pipe 10 is prepared, and the U-shaped heating wire 20 is sequentially inserted into the through holes 33 of the first insulated body 30 and the second insulated body 31 to prepare a pipe interior. Inserting the pipe interior into the pipe 10, inserting a silicone stopper 40 into one end of the pipe 10, and filling the insulator 60 into the pipe 10. , Inserting the terminal portion 70 into the other end of the pipe 10, inserting the pipe internal body into the pipe 10, inserting the silicone stopper 40, filling the insulator 60, and inserting the terminal portion 70. After this is done, the step of conduit pipe 10 by the conduit roller, the step of fixing the cover 50 to the end of the conduit pipe 10; characterized in that consisting of.

In addition, the first and second insulating molded bodies 30 and 31 are formed with two through holes 33 into which the U-shaped heating wire 20 can be inserted, and the first insulating molded body 30 has a circular portion. It has a plate-like shape consisting of 34 and the vertical portion 35, the circular portion 34 is characterized in that the shape of the same curvature as the pipe (10).

And the second insulating molded body 31 is characterized in that it consists of a circular plate shape of a diameter smaller than the diameter of the pipe (10).

On the other hand, the cover 50 is fixed by pressing in the circumferential direction or fixed in the longitudinal direction, the insulator 60 is characterized in that the surface is coated with silicon oxide as magnesium oxide.

According to the present invention,

● It is easy to fill the insulation by maintaining the heat wire alignment state inside the pipe when filling the insulation.

● Insulation does not leak during the condensation process, so the insulation density in the pipe is maintained accurately, which improves thermal efficiency.

● In addition, by disposing the heating wires embedded in the pipe in a U-shape, the magnetic field is canceled to reduce the risk of electromagnetic waves.

1 is a perspective view of the interior of the electrothermal heating pipe according to the present invention
2 is a cross-sectional view of the electrothermal heating pipe according to the present invention.
3 is an enlarged view of the pipe end;
4 is a cross-sectional view of the first insulating molded body inserted into the pipe;
5 is a perspective view of a first insulating molded body
6 is a perspective view of another embodiment of a first insulating molded body
7 is a perspective view when the pipe of the present invention is circular
8 is a perspective view when the pipe of the present invention is elliptical
9 is a flowchart of a manufacturing method according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

First, the electrothermal heating pipe which is a manufacturing target of the present invention will be described below.

Each of the components of the electrothermal heating pipes used in the method of manufacturing the electrothermal heating pipes of the present invention, as shown in Figures 1 to 8, the pipe 10 is a U-shaped heating wire 20 is built in the longitudinal direction therein, the pipe (10) a first stopper for inserting a silicone stopper 40 inserted into one end portion, an insulator 60 filled in the pipe 10, and received in the pipe 10 and fixing the U-shaped heating wire 20. The molded body 30, the second insulating molded body 31 accommodated in the pipe 10 to support the U-shaped heating wire 20, the terminal part 70 inserted into the other end of the pipe 10, and the silicon It comprises a; cover 50 is fixed to the end of the pipe 10 is inserted into the stopper 40.

Electrothermal heating pipe manufacturing method of the present invention, as shown in Figure 9,

Preparing a pipe 10, preparing a pipe interior by sequentially inserting the U-shaped heating wire 20 into the through holes 33 of the first insulating molded body 30 and the second insulating molded body 31, Inserting the pipe interior into the pipe (10), inserting a silicone stopper (40) at one end of the pipe (10), filling the insulator (60) inside the pipe (10), and the pipe After inserting the terminal portion 70 to the other end of the (10), after the insertion of the pipe internal body into the pipe 10, the insertion of the silicone stopper 40, filling the insulator 60, after inserting the terminal portion 70 Condensing the pipe (10) by the conduit roller, the step of fixing the cover 50 to one end of the conduit pipe (10);

In the preparing of the pipe 10, the pipe 10 is mainly made of stainless steel as a material having rigidity enough to form a crimping portion (a) at the pressing portion. The cross section of the pipe 10 is not limited to circular but may be elliptical. If the cross section of the pipe 10 is elliptical, there is an advantage that the heating area can be wider.

Next, according to the present invention, the U-shaped hot wire 20 is sequentially inserted into the through holes 33 of the first insulating molded body 30 and the second insulating molded body 31 to prepare a pipe interior.

Inside the pipe 10, the U-shaped hot wire 20 is disposed to heat the heater by applying electricity as described in the related art. The U-shaped array of hot wires is generated in each hot wire because the hot wires are arranged in parallel up and down. The magnetic field can act as a mutual offsetting to reduce the electromagnetic risk caused by the use of electrical appliances.

The pipe internal body is formed by sequentially inserting the U-shaped heating wire 20 into the through hole 33 of the first insulating molded body 30 and the second insulating molded body 31, and is inserted into the pipe 10. to be.

The first insulating molded body 30 is formed by compression molding a white powder-like magnesia made of the same material as the insulator, and two through holes 33 are formed to be spaced apart from each other to insert the U-shaped heating wire 20. It is supposed to be. Such a through hole 33 is also formed in the second insulating molded body 31 or further insulating molded body accommodated in the pipe 10.

In addition, the first insulating molded body 30 has a plate shape consisting of a circular portion 34 and a vertical portion 35, and the circular portion 34 has the same curvature as that of the pipe 10 to be inserted into the pipe 10. It is preferable to maintain the fixed state, and the outside of the insulator 60, which is filled with the vertical part 35, may be filled up to the silicon stopper 40 through a gap between the vertical part 35 and the pipe 10. . The shape of the gap is not necessarily limited to the vertical portion, and any shape may be sufficient as long as it forms a gap with the pipe, and as shown in FIG. 6, a plurality of semicircular grooves along the circumference of the circular portion 34 in the longitudinal direction. You may form.

In addition, the second insulating molded body 31 supporting the U-shaped heating wire 20 is accommodated in the pipe 10 of the present invention. The heating wire accommodated in the pipe 10 may vary in the winding density and length of the heating wire according to the amount of heat generated and the installation area. When the length of the heating wire becomes longer, the U-shaped heating wire embedded in the pipe sags before filling the insulation or If the insulator 60 is charged and energized in this state, a short circuit may occur. The second insulating molded body 31 of the present invention is configured to maintain the alignment state of the heating wire and to prevent twisting.

In addition, the second insulating molded body 31 has a circular plate shape having a diameter smaller than that of the pipe 10. As described above, the length of the heating wire to be accommodated in the pipe 10 needs to vary depending on the amount of heat generated and the installation area. In addition to the method of lengthening the length of the heating wire, the length of the heating wire is extended to fit the pipe length. There is also.

When the hot wire is inserted into the through hole 33 of the second insulating molded body 31, the end of the hot wire is straightened, then inserted into the through hole 33 and pulled out, and the twisted state of the hot wire is unfolded. After passing through and releasing the pulling force, the twisting state of the heating wire is restored again, so that the second insulating molded body 31 inserted into the heating wire cannot be easily moved from side to side at the insertion position of the heating wire, and the insulator 60 is attached to the pipe 10. Even if it is charged, the position of the second insulating molded body 33 does not change.

The second insulating molded body 31 of the present invention has the above configuration, and when the U-shaped hot wire 20 is inserted into the through hole 33 of the second insulating molded body 31, the second insulating molded body is extended. Since 31 is free without contacting or pinching the pipe 10, the heating wire can be freely extended in the pipe 10 to flexibly respond to the required heating generation amount and the installation area.

At this time, the first insulating molded body 30 remains fixed in the pipe 10. The first insulating molded body 30 is pulled when extending the hot wire by making the circumferential surface of the first insulating molded body 30 into a tapered cone. ) Is more preferably press-fitted inside the pipe 10 and is fixed by friction. Since the first insulating molded body 30 is a material in which magnesia powder is press-molded, even if the size of the pipe 10 is not exactly matched with the inner diameter of the pipe 10, the first insulating molded body 30 may be ground immediately to adjust the size and press-fit the pipe 10. In addition, the first insulating molded body 30 may be fixed by pressing the outside of the pipe 10 in the circumferential direction at the insertion position of the first insulating molded body 30.

As described above, after the U-shaped heating wire 20 is sequentially inserted into the through-hole 33 of the first insulating molded body 30 and the second insulating molded body 31 to prepare a pipe interior, the pipe interior is piped ( 10), and then the silicone stopper 40 is inserted into one end of the pipe 10. The silicone stopper 40 is configured to seal one end of the pipe 10 to prevent the insulator 60 inside the pipe 10 from leaking during the condensation process, thereby preventing the lowering of the packing density of the insulator.

Subsequently, the insulator 60 is filled in the pipe 10. The insulator 60 is usually magnesium oxide (MgO, Magnesia) in the form of white powder. 10) It is enough to use the method of vibrating while filling the insulation.

After the insulator 60 is filled in the pipe 10, the terminal portion 70 is inserted into the other end of the pipe 10. The terminal part 70 is made of the same material as the silicone stopper 40, and performs a sealing function of the other end of the pipe 10, and is connected to a terminal for applying a current to the heating wire 20 as a terminal connection structure It is a normal structure.

After inserting the pipe internal body and the silicone stopper 40 into the pipe 10 as described above, and filling the insulator 60, and inserting the terminal portion 70, the pipe 10 by the conventional shaft roller roller do. At this time, the magnesia insulator 60 inside the pipe 10 is compressed to discharge the air inside the pipe, and the insulator 60 and the first and second insulation molded bodies 30 and 31 used in the present invention are all made of magnesia. In the process, the shape is crushed and turned into a powdered form. Therefore, when the conduit process is completed, the insulator 60 and the first and second insulators 30 and 31 all function as an insulator.

Finally, the cover 50 is pressed and fixed to one end of the condensed pipe 10, that is, the end of which the silicone stopper 40 is inserted. The encapsulation portion of the heating heater cannot completely rule out the possibility of failure during use or during the manufacture of the product. As a result, when water penetrates through the encapsulation part and the insulator expands, pipe burst and short circuit may occur.

In the present invention, the cover 50 is covered at one end of the pipe 10 into which the silicone stopper 40 is inserted, and a predetermined portion of the cover 50 is pressed and fixed by pressing. The pressing is formed along the circumferential surface of the cover 50 or in the longitudinal direction of the cover 50 to form a crimping portion a on the cover 50. When pressing is performed as described above, grooves corresponding to the crimping portion a are sequentially formed in the cover 50, the pipe 10, and the silicone stopper 40 to fix the silicone stopper 40 and the pipe 10. It keeps the sealed state and prevents the penetration of external moisture.

The present invention also presents an insulator coated with silicon as another embodiment of the insulator 60. In other words, when the magnesia material used as an insulator is immersed in a silicone solution and dried, silicon is coated on the surface of the magnesia particles. The coated particles are insulated even though moisture penetrates into the pipe from the outside. Expansion does not occur and consequently no pipe rupture or leakage.

 The working relationship of the present invention is as follows.

According to the present invention, even if the first insulating molded body 30 fixing the heating wire in the shaft tube process is broken, the silicone stopper 40 seals the pipe 10 separately, so that the insulation inside the pipe 10 leaks or moisture from the outside into the inside. It cannot penetrate. In addition, since the cover 50 is separately fixed to the pipe 10 after completion of the conduit process, even if the silicone stopper 40 is damaged, external moisture can be prevented from penetrating.

In the pipe 10 of the present invention, since the heating wire is disposed in a U-shape, the magnetic fields generated in each heating wire are attenuated.

Since the first insulating molded body 30 of the present invention has a plate shape consisting of a circular portion 34 and a vertical portion 35, the circular portion 34 maintains a fixed state in the pipe 10 and the vertical portion 35 Since the insulation 60 may be filled up to the silicon stopper 40 through), the heating wire is not exposed to the outside at all. Therefore, hot wire breakage can not occur during use or careless handling of the work process.

In addition, the second insulating molded body 31 of the present invention supports the heating wire in parallel when the length of the heating wire is long, so that the heating wire is not twisted, so the filling process of the insulation is easy, and there is no fear of short-circuit, thereby significantly reducing the defective rate of the finished product. do.

In addition, since the second insulating molded body 31 has a circular plate shape having a diameter smaller than the diameter of the pipe 10, the length of the heating wire may be elastically extended while the heating wire is supported in parallel. If necessary, many supporting molded bodies such as the second insulating molded body 31 may be provided.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10 pipe 20 heat wire
30: first insulating molded body 31: second insulating molded body
33 through hole 34 circular portion 35 vertical portion
40: silicone stopper 50: cover
60: insulator 70: terminal

Claims (6)

Preparing the Pipe 10
Preparing a pipe internal body by sequentially inserting the U-shaped heating wire 20 into the through holes 33 of the first insulating molded body 30 and the second insulating molded body 31;
Inserting the pipe interior into the pipe (10),
Inserting a silicone stopper 40 at one end of the pipe 10;
Filling the insulator 60 into the pipe 10;
Inserting the terminal portion 70 into the other end of the pipe 10,
Condensing the pipe 10 by the conduit roller after inserting the pipe internal body into the pipe 10, inserting the silicone stopper 40, filling the insulator 60, and inserting the terminal portion 70.
And pressing and fixing the cover (50) at one end of the condensed pipe (10).
The method of claim 1,
The first and second insulating molded body (30, 31) is a method for manufacturing an electric heating pipe, characterized in that the two through-holes (33) in which the U-shaped heating wire (20) can be inserted are formed spaced apart from each other.
The method of claim 1,
The first insulating molded body 30 has a plate shape consisting of a circular portion 34 and a vertical portion 35, wherein the circular portion 34 has a shape of the same curvature as that of the pipe 10. Pipe manufacturing method.
The method of claim 1,
The second insulating molded body 31 is a method of manufacturing an electrothermal heating pipe, characterized in that made of a circular plate shape having a diameter smaller than the diameter of the pipe (10).
The method of claim 1,
The cover 50 is characterized in that the pressurized fixed by pressing in the circumferential direction.
The method of claim 1,
The insulator 60 is magnesium oxide, the surface of which is coated with silicon, characterized in that the heating pipe manufacturing method.

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