KR20230000600U - Electrical Heater Jacket for cylinderical pipe employing specially designed insulation - Google Patents

Abstract

In the case of an electric heater jacket using a conventional insulation material thicker than 30T, due to the thickness of the insulation material, when attaching to the pipe 500, it is necessary to pull and bind with force. and reduce the insulation effect, and also poses a problem in that the durability of the jacket is reduced by increasing the insulation material and the outer covering material when attached to the pipe 500 for a long time.
The present invention, in order to solve and supplement the above problems such as the inconvenience of mounting, the decrease in adhesion and insulation effect, and the decrease in durability of the jacket, the main insulator 100a having a thickness of 20T or more in which a plurality of incisions 100c are formed and Provides a structure related to an electric heater jacket for cylindrical piping, characterized in that it is completed by adopting a double insulation part (100) of a special structure formed by combining auxiliary insulation (100b) of high-density material with a relatively long width and thin thickness. .

Description

Electrical Heater Jacket for cylindrical pipe employing specially designed insulation}

The present invention relates to a structure of an electric heater jacket that surrounds the outer circumferential surface of a pipe through which a fluid flows and heats the pipe by energization.

In order to maintain an appropriate temperature of the fluid flowing inside various cylindrical pipes installed in semiconductor production facilities, electric heater jackets are commercially available that cover the outer circumferential surface of the pipe and generate heat by energizing to transfer heat to the pipe.

The above electric heater jacket is basically composed of an inner skin, a heat-resistant cloth with heating wires, a heat insulating material, an outer skin, and a binding member as common elements, and the heat insulating material used here is mainly made of inorganic materials such as glass fiber, silica fiber, and aramid fiber. As a plate-like structure in the form of wool or felt, it is molded in various thicknesses according to the physical characteristics of each material and the target insulation effect.

In order to attach the conventional jacket to the pipe, the jacket is wrapped around the outer circumferential surface of the pipe, and the binding member attached to the outer jacket is pulled and tightened with force so that the cross-sections on both sides of the jacket are in complete contact with each other. At this time, the curved surface along the circumference of the pipe The insulating material inside the jacket forming a plurality of wrinkles in the longitudinal direction of the pipe is formed on one side of the insulating material facing the outer circumferential surface of the pipe due to its own thickness and the applied external pressure, reducing the degree of adhesion to the pipe and reducing the insulation effect. There is a problem that becomes, in general, the smaller the outer diameter of the pipe and the thicker the insulation, the more so.

In addition, as described above, when the electric heater jacket is firmly attached to the pipe, tensile force acts on the jacket, the binding member, and the insulator, so that after a long period of time, the jacket is gradually stretched, reducing durability of the jacket.

The present invention is mainly intended to solve and improve the above problems occurring in the case of an electric heater jacket that requires thick insulation of 30T or more, and the conventional electric heater jacket has a curved surface along the circumference of the pipe due to the thick insulation inside. It is not easy to bend smoothly, which solves the inconvenience of having to pull the connecting member coupled to the outer shell with force when mounting on the pipe, and the decrease in durability of the jacket due to the sagging of the outer skin caused by this, and also the insulation material facing the outer circumferential surface of the pipe It is an object of the present invention to provide a structure of an electric heater jacket employing a specially designed insulation part to prevent deterioration of adhesion to the pipe surface and insulation effect due to a plurality of wrinkles formed on one surface of the heater.

In order to achieve the above object, the heat insulating part 100 employed in the electric heater jacket for pipe according to the present invention is a main heat insulating material (100a) in which a plurality of cut lines (100c) are formed side by side in the longitudinal direction of the pipe (500) on one surface. And, it is characterized by consisting of an auxiliary insulator (100b) disposed superimposed on one surface on which the incision (100c) of the main insulator (100a) is formed.

The incision 100c is formed using a cutter 800 at a depth 40 shallower than the thickness t 20 of the main insulator 100a so that the main insulator 100a is not completely cut. The thickness of the remaining main insulator (100a) is 10T to 15T.

The auxiliary insulator 100b uses a thin insulator that is easy to form a curved surface, and preferably, a high-density insulator having a thickness of about 10T may be used.

In addition, the width of the main insulator (100a) is cut to the same length as the length of the outer circumference of the pipe, and the width of the auxiliary insulator (100b) is the outer circumferential radius r (30) of the pipe and the thickness t (20) of the main insulator (100a) It is characterized in that it is cut to a length equal to the circumference length {2π (r + t)} for the summed total radius (r + t).

In addition, a double space 100d is formed between the two insulators by overlapping one side of the main insulator 100a on which the incision 100c is formed and one side of the auxiliary insulator 100b and matching both ends in the width direction and combining them with a tacking needle. It is characterized by providing an insulator (100).

In order to complete the electric heater jacket employing the double insulation part 100, a heat-resistant cloth 300 to which hot wires 300a arranged in a predetermined pattern are coupled to one side of the heat insulation part 100 facing the pipe, and The inner shell 200 is sequentially disposed, and the outer shell 400 to which the binding member 400a is coupled is disposed on the other side of the heat insulating unit 100 .

Preferably, the width and length of the inner shell 200 are cut longer than the main heat insulator 100a so that it can be turned and covered on all sides of the heat insulating part 100, and the width and length of the outer shell 400 are It can be cut in the same way as the auxiliary insulator (100b).

As described above, a space 100d is formed between the main insulator 100a and the auxiliary insulator 100b of the insulator 100 employed in the electric heater jacket for piping according to the present invention, and the main insulator ( A plurality of incisions 100c are formed on one side of 100a) at predetermined intervals, so when the electric heater jacket is wound around the pipe, the gap 10 between the incisions 100c of the main insulator 100a within the space 100d. ) is flexibly opened, so wrinkles 900 are not formed on one side of the main insulator 100a in contact with the heat-resistant cloth 300, so that the adhesion with the pipe is improved and the insulation effect is prevented from deteriorating.

In addition, the widened upper end of the gap 10 of the incision 100c comes into contact with one surface of the main insulator 100a inside the heat insulating part 100, so that a plurality of long and narrow pipes parallel to the longitudinal direction of the pipe 500 Since the air pockets 10 are formed, the insulation effect is reinforced.

In addition, the width of the outer shell 400 and the auxiliary insulator 100b is designed to be wider than the width of the main insulator 100a equal to the circumferential length of the pipe 500 by reflecting the thickness 20 of the main insulator 100a. When the heater jacket is wrapped around the pipe and mounted, no pressure is applied to the outer shell 400 and the heat insulating part 100, so there is no need to apply excessive force to pull the binding member 400a, and the outer shell 400 and the heat insulation due to long-term installation Since the sagging of the part 100 does not occur, it helps to maintain the durability of the electric heater jacket.

1 is an exploded perspective view of a heat insulating unit according to an embodiment of the present invention.
2 is an exploded front view and a longitudinal cross-sectional view of a pipe in an unfolded state of an electric heater jacket employing a heat insulating unit according to an embodiment of the present invention.
3 is a longitudinal cross-sectional view and a perspective view of a state in which an electric heater jacket employing a thermal insulation unit according to an embodiment of the present invention is mounted on a pipe.
Figure 4 shows a plan view of an incision line forming auxiliary tool and a method of forming an incision line according to an embodiment of the present invention.
5 is a longitudinal sectional view of a state in which a conventional electric heater jacket is mounted on a pipe.

The present invention is not limited to the embodiments disclosed below, but may be implemented in various forms similar to each other, and is provided to completely inform those skilled in the art of the scope of the invention, and various equivalents or It should be understood that there are substitutes and variations.

On the other hand, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted, and in describing the accompanying drawings, the same components Note that the same reference numerals are given regardless of reference numerals.

Hereinafter, the structure of an electric heater jacket for a cylindrical pipe employing the heat insulation unit 100 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

A general electric heater jacket used to maintain an appropriate temperature of fluid flowing inside various cylindrical pipes installed in a production process of semiconductors, etc. includes an insulating material having a predetermined thickness; a heat-resistant wire cloth in contact with one surface of the heat insulating material and having heat wires arranged in a predetermined pattern; an endothelial material in contact with one side of the outer circumferential surface of the pipe and the other side with the heat-resistant cloth; It is composed of a basic element; an outer shell material in contact with the other surface of the heat insulating material and to which a binding member is coupled.

The electric heater jacket employing the heat insulation unit 100 according to the present invention mainly faces the outer circumferential surface of the pipe when a conventional electric heater jacket employing a thick single-layer plate-shaped insulation material having a thickness of 20T or more is mounted on the pipe 500. The problem of deterioration of the insulation effect due to the wrinkles 900 formed on one side of the insulator, the inconvenience of having to pull and bind the binding member coupled to the outer cover material, and the decrease in durability of the electric heater jacket due to the applied pressure It is specially designed to prevent

1 is an exploded perspective view of a heat insulating unit 100 according to the present invention, and FIG. 2 is a front exploded view and a longitudinal cross-sectional view of a pipe in an unfolded state of an electric heater jacket employing the heat insulating unit 100 according to the present invention. 1 and 2, the insulator 100 according to the present invention has a dual structure in which a main insulator 100a and a secondary insulator 100b are combined.

The main insulator 100a may be in the form of wool or felt made of inorganic materials such as glass fiber, silica fiber, and aramid fiber, and may have a plate-shaped structure mainly formed to a thickness of 20T or more.

The main insulator 100a is cut to the same width as the outer circumference of the pipe 500, and a plurality of incisions 100c are formed on one surface in parallel with the longitudinal direction of the pipe.

4 is a plan view of the incision line 100c forming auxiliary plate 700 and an operation of forming the incision line 100c using the stationery cutter 800 from the side.

Referring to FIG. 4, the depth 40 of the incision 100c should be formed to a depth shallower than the thickness 20 of the main insulator, preferably at least half the depth of the thickness 20 of the main insulator, The thickness of the uncut portion of the main insulation 100a should not be less than 10T, and the incision 100c can be conveniently formed using the incision forming auxiliary plate 700 and the cutter 800 for general stationery. there is. More specifically, after disposing the incision line forming auxiliary plate 700 on one side of the main insulator 100a, the length of the cutter 800 is adjusted and fixed by the depth 40 of the predetermined incision line 100c, and the cutter ( 800) may be inserted into the slit 700a to uniformly form the cutting line 100c throughout the cutter holder 800a.

The auxiliary insulator 100b has a plate-like structure formed of a material with a relatively smaller thickness and higher density than the main insulator 100a, and may be formed of a high-density aramid material having a thickness of 10T.

에 대한 원주 길이

와 동일한 길이의 폭으로 재단된 것을 특징으로 한다.In addition, the auxiliary insulator 100b has a total radius obtained by adding the thickness t (20) of the main insulator 100a to the outer circumferential radius r (30) of the pipe 500 (

circumferential length for

It is characterized in that it is cut to a width of the same length as.

Next, one side of the main insulator 100a where the incision line 100c is formed and one side of the auxiliary insulator 100b are overlapped and both ends in a direction parallel to the length of the incision line 100c are combined with a tack to create a space between the two insulators. (100d) is formed to form a heat insulating portion 100 of a double structure to ensure.

In order to complete the electric heater jacket employing the above-mentioned heat insulation part 100 according to the present invention, one surface of the heat-resistant cloth 300 in which heating wires 300a are fixedly arranged in a predetermined pattern and the main heat insulating material of the heat insulation part 100 One surface of (100a) is brought together with a tacking needle, and the endothelium 200 is placed on the other surface of the heat-resistant cloth 300 and bonded with a tacking needle. Preferably, the width and length of the endothelial 200 are cut to be longer than the heat-resistant cloth 300, and heat loss can be prevented by turning and covering the open side of the four ends of the heat insulating part 100 and combining them with a tack.

In addition, one surface provided with the binding member 400a of the outer shell 400 and the other surface provided with the binding member 400a of the outer shell 400 are superimposed on one surface of the auxiliary insulator 100b of the heat insulating part 100 to which the inner shell 200 is coupled, and bonded with a tack. Preferably, the outer shell 400 may have the same width and length as the auxiliary insulator 100b of the insulator 100, and then combine them.

3 is a longitudinal cross-sectional view and an external perspective view of a state in which the electric heater jacket employing the heat insulation unit 100 according to the present invention completed as described above is wrapped around the pipe 500 and mounted.

Referring to FIG. 3, when the electric heater jacket of the present invention is wound around and mounted on a pipe 500, an incision 100c is formed on one side of the main insulator 100a in the space 100d formed inside the heat insulator 100. ) As the gaps 10 of the gaps 10 are flexibly widened, the upper end of the gaps 10 comes into contact with one surface of the auxiliary insulator 100b to form a plurality of long and narrow air pockets 10 inside the heat insulator 100. Since the effect is reinforced and the wrinkles 900, which is a problem of the conventional electric heater jacket shown in FIG. 5, are not formed on the other side of the main insulator 100a, the adhesion to the pipe 500 and the insulation effect due to heat loss are reduced. It is characterized in that it is designed to help maintain the durability of the electric heater jacket by being able to prevent it and firmly attaching it to the pipe 500 without pulling by applying excessive force to the outer shell 400 and the binding member 400a.

100: heat insulation
100a: main insulation 100b: auxiliary insulation
100c: incision 100d: space inside the insulation
200: endothelium
300: heat-resistant cloth 300a: heat wire
400: outer shell 400a: binding member
500: piping 600: power lead wire
700: incision forming auxiliary plate 700a: slit
800: cutter 800a: cutter holder
900: corrugation of the main insulation
10: Gap of main insulation, air pocket 20: Thickness of main insulation (t)
30: Radius of the outer circumferential surface of the pipe (r) 40: Incision depth

Claims (3)

In the electric heater jacket for cylindrical pipes installed in semiconductor manufacturing facilities, etc.
A plurality of incisions 100c are formed at predetermined intervals in the longitudinal direction of the pipe 500 on one surface, and when wound on the circumferential surface of the pipe 500, the gap 10 of the incisions 100c widens and flexibly bends into a curved surface. The main insulator (100a), characterized in that;
A secondary insulator (100b) formed to have a longer width and a smaller thickness than the main insulator (100a);
A structure in which a space 100d is formed between the two insulators by overlapping one side of the auxiliary insulator 100b on one side of the main insulator 100a on which the incision 100c is formed and combining the left and right ends of the width with a tacking needle. double insulation (100);
Centered on the heat insulating part 100, the heat-resistant cloth 300 and the inner skin 200 in which the heat wire 300a is disposed and fixed in a predetermined pattern are sequentially laminated and bonded to one side of the main heat insulating material 100a, and the auxiliary heat insulating material It is completed by combining the outer shell 400 provided with the binding member 400a on one side of (100b), and is flexible in bending along the outer circumferential surface of the pipe and has reinforced insulation effect and durability. Electric heater jacket for cylindrical pipe; According to claim 1,
The main insulator 100a has a thickness of 30T or more, and the incision line 100c has a thickness of the remaining portion of the main insulator 100a between 10T and 15T, so that the main insulator 100a is not completely cut. An electric heater jacket characterized in that it is devised with a thickness that is easy to bend into a curved surface without bending; According to claim 1,
The auxiliary insulator (100b) is a relatively high-density material than the main insulator (100a), the thickness is formed between 10T ~ 15T is easy to bend, and the width is the outer circumferential radius (r) of the pipe and the thickness of the main insulator (100a) An electric heater jacket characterized in that it is cut to a length equal to the circumferential length {2π(r+t)} for the total radius (r+t) of (t);

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