KR101951791B1 - Multiple tubes with insulation and multiple tubes manufacturing apparatus - Google Patents

Abstract

Disclosed are a multiple tubes having a compressed heat insulation material and an apparatus for manufacturing the same. The multiple tubes includes: a high pressure pipe and a low pressure pipe surrounded by a heat insulation material; a casing heat-reserving material surrounding the high pressure pipe and the low pressure pipe; and a coating layer for coating the casing heat-reserving material, wherein the heat insulation material is compressed and surrounded by the casing heat-reserving material, or multiple tubes, which are wrapped by a thread instead of the casing heat-reserving material and compressed, are provided. Accordingly, the multiple tubes in which the heat insulation material is compressed and surrounded by the casing insulation material or the thread are provided, so that the multi-purpose tube includes a communication line and a wire therein to provide the multiple tubes. The multiple tubes further includes a drain tube to discharge water through the drain tube, the heat insulation material is compressed through a compression tube, the casing heat-reserving material surrounds the heat insulation material compressed through a casing adhesive tube, and the coating layer is shrunk by hot air or air jet, so that the multiple tubes are manufactured. Both ends of the casing heat-reserving material are overlapped upward and downward, respectively, the overlapped portions are adhereing to each other by applying hot air to surround the compressed heat-reserving material, the compression tube is selected according to the degree of compression of the heat insulation material, and the casing adhesive tube is selected to surround the compressed heat insulation material so as to form an outer diameter of tubes, so that the multiple tubes are manufactured. The coating layer coats the multiple tubes, so that the multiple tubes has a strength against external scratches and tears.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a multi-tube and multi-

The present invention relates to an apparatus for producing a multiple tube and a multi-tubular body in which a heat insulating material is compressed, and more particularly to a multi-tubular and multi-tubular manufacturing apparatus in which a compact heat-insulating material is compressed.

Multiple tubes are used for air conditioning piping. When piping is applied, the tape is wrapped around multiple tubes. When the heat insulating material is compressed, there is a problem that the heat insulating performance is deteriorated and the water condenses on the multi-tubular body. Further, when the multi-tube is installed without being compressed, there is a problem that it can not pass through the small hole due to the volume of the heat insulating material. When the multi-tubular body is finished with tape to pass through a small hole, the heat insulating material may be squeezed too much to deteriorate the heat insulating performance, thereby causing the water to condense and fall. It is necessary that the multi-tubular body should pass through small holes without deteriorating the insulation performance.

Patent No. 10-0572755, piping device for air conditioner and manufacturing method thereof Patent No. 10-0749300, Multi-tube manufacturing apparatus and manufacturing method thereof Patent No. 10-1168713, Multiple Tubes, Manufacturing Apparatus and Manufacturing Method Korean Patent Registration No. 10-1088039, refrigerant tube for air conditioner and production method thereof

In order to solve the above problems, an object of the present invention is to provide a multichannel and multi-tube manufacturing apparatus in which a compact heat insulating material is compressed.

In addition, it is a further object to provide a multi-tubular body in which a heat insulating material capable of having a multipurpose pipe including a communication line and a wire is compressed.

It is also an object of the present invention to provide a multi-tubular body in which a heat-insulating material capable of discharging water is compressed.

It is also an object of the present invention to provide a multiple tube body in which the insulation is compressed.

It is also an object of the present invention to provide a multi-tubular body in which a heat insulating material capable of wrapping a compressed heat insulating material is compressed.

It is also an object of the present invention to provide a multi-tubular body in which a heat insulating material resistant to external scratches and tears is compressed.

To achieve the above object, the present invention provides a high pressure pipe and a low pressure pipe surrounded by a heat insulating material; A casing insulation surrounding the high pressure pipe and the low pressure pipe; And a coating layer coating the mantle insulator, wherein the insulator is compressed and wrapped with a mantle insulator.

Also, a high-pressure pipe and a low-pressure pipe surrounded by a heat insulating material; A casing insulation surrounding the high pressure pipe and the low pressure pipe; A yarn for winding the mantle insulator crosswise in one direction or in different directions; And a coating layer for coating a yarn-wrapped casing insulation.

The multi-tubular body further includes a multi-purpose pipe connected to the high-pressure pipe and the low-pressure pipe, and the multipurpose pipe includes a communication line and an electric wire inside.

Further, the multi-tubular body further includes only the wires in the high-pressure pipe and the low-pressure pipe.

The multi-tubular body further includes a drain pipe.

Further, the heat insulating material is compressed through the compression tube, and the mantle insulating material surrounds the heat insulating material compressed through the sheathing adhesive tube, and the coating layer is contracted by hot air or air jet.

Further, both ends of the mantle insulating material are overlapped with each other, and hot air is applied to the overlapped portions.

Further, the compression pipe is selected according to the degree of compression of the heat insulating material, and the sheath adhesion pipe is selected so that the pipe outer diameter is formed by covering the compressed heat insulating material.

Further, the material of the heat insulating material and the outer surface heat insulating material is crosslinked expanded polyethylene, and the hot air temperature is 80-200 deg. C close to the polyethylene melting temperature.

Also, the coating layer is a flexible resin, EVA (Ethylene Vinyl Acetate) or PVC coating, and the hot air temperature is 200 DEG C, allowing the coating layer to flow and shrink while sticking to multiple tubes.

Further, a compression unit for compressing the heat insulating material in the high pressure pipe and the low pressure pipe surrounded by the heat insulating material; And a coating portion for coating on the heat insulating material.

The compression unit may include a conveying unit that surrounds and conveys the heat insulating material to the high pressure pipe and the low pressure pipe, compresses the heat insulating material by passing the high pressure pipe and the low pressure pipe surrounded by the heat insulating material through the compression pipe, A sheath adhesive section which surrounds the high-pressure pipe and the low-pressure pipe with a high-pressure pipe and a low-pressure pipe through which the heat insulating material is compressed, And a coating portion for forming a coating layer on the outer surface heat insulating material.

The compression unit may include a conveying unit that surrounds and conveys the heat insulating material to the high pressure pipe and the low pressure pipe, compresses the heat insulating material by passing the high pressure pipe and the low pressure pipe surrounded by the heat insulating material through the compression pipe, A sheath adhesive section which surrounds the high-pressure pipe and the low-pressure pipe with a high-pressure pipe and a low-pressure pipe through which the heat insulating material is compressed, A taping portion which winds around the outer circumferential heat insulating material while crossing the yarns in different directions; And a coating portion for forming a coating layer on the outer surface heat insulating material.

Also, the taping portion may be a failure in which the thread is wound; A ceramic guide for guiding the thread of failure; A tension unit for applying tension to the yarn guided by the ceramic guide; A guide for guiding the yarn passed through the ceramic guide to the ceramic nozzle; And a rotating part wound around the room multi-tubular body passing through the ceramic nozzle.

When the multi-tubular body according to the present invention as described above is used, it is possible to provide a multi-tubular body in which the heat-insulating material is compressed and enclosed by the enclosure insulator.

In addition, the multi-purpose pipe has an advantage of forming a multi-pipe body including a communication line and an electric wire inside.

In addition, the multi-tubular body may further include only wires to reduce its appearance.

In addition, the multi-tubular body may further include a drain pipe to discharge water through the drain pipe.

Further, the heat insulating material is compressed through the compression tube, the external heat insulating material surrounds the heat insulating material compressed through the sheathing adhesive tube, and the coating layer is contracted by hot air to form multiple tubes.

Further, both ends of the mantle insulator overlap each other, and hot air is applied to the overlapped portions, so that the compressive insulator can be wrapped.

Further, the compression pipe is selected according to the degree of compression of the heat insulating material, and the shell adhering pipe is selected so as to cover the compressed heat insulating material and to form the pipe outer diameter, so that multiple pipes can be manufactured.

In addition, the coating layer may be coated with multiple tubular bodies so that the multiple tubular bodies are robust against external scratches and tearing.

In addition, the yarn can be wound around the multiple tubes in one direction or in different directions to compress the heat insulating material and the mantle insulating material.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a configuration of a multi-tube manufacturing apparatus. FIG.
Fig. 2 is an exemplary view showing a multi-tubular body.
3 is an exemplary view showing a multi-tube cross section.
4 is an exemplary view illustrating a method for manufacturing a multi-tubular body.
5 is a view showing an example of a multi-tubular body in which a yarn is wound and coated on a casing insulator.
6 is a view showing an example of a multi-tubular body in which a yarn is wound and coated without a shell insulation.
7 is an exemplary view showing a configuration of another embodiment of a multi-tube manufacturing apparatus.
8 is an exemplary view showing a configuration of the taping portion 50. As shown in Fig.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

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

The multi-tubular manufacturing apparatus can provide multiple tubes that are compressed by the heat insulator and wrapped with a skin insulator. Insulation is compressed to reduce multiple tube volumes. Air conditioning piping work can be made easier than before. The multi-purpose pipe has the advantage of constructing multiple tubes including communication lines and wires inside. The multipurpose pipe can store a communication line or an electric wire connected between the air conditioner and the outdoor unit. Since the communication line or the wire is not exposed to the outside, the aesthetic appearance may be beautiful. The multi-tubular body may further include a drain pipe to discharge the water through the drain pipe. The water pipe allows the water generated from the air conditioner to be discharged outdoors.

The heat insulating material is compressed through the compression tube, and the coating layer that encloses the heat insulating material compressed through the sheath adhesive tube and the sheath insulating material is shrunk by hot air or air blowing to form multiple tubes. The compression tube is selected in accordance with the degree of compression of the heat insulating material, and the shell adhering tube is selected so that the outer diameter of the tube is surrounded by the compressed heat insulating material so that multiple tubes can be manufactured. Both ends of the mantle insulation are overlapped by the upper and lower parts, and hot air is applied to the overlapping parts, so that the compressed insulation can be wrapped. The mantle insulation can increase the insulation performance of multiple tubes. The coating layer may be coated with multiple tubular bodies to provide robustness against external scratches and tears. If the jacket insulation is resistant to external scratches and tearing, the coating layer may be omitted.

A multi-pipe structure for a refrigerant connecting an air conditioner and an outdoor unit, comprising: a high-pressure pipe and a low-pressure pipe; Pressure tube and a low-pressure tube, and the insulation is compressed by the compression means. The compression means may be a cloth, tape or thread that winds the insulation, or may be a casing insulation surrounding the insulation. Indeed, the wire form may be a fiber such as glass fiber, a polymeric fiber such as a fishing line, or a wire such as a wire. The multi-tubular body may include a coating layer coating the heat insulating material compressed to the winding chamber. The compression means is a casing insulation surrounding the insulation, and may comprise a coating layer coating the casing insulation. The mantle insulation can be compressed by wrapping the insulation in a flexible tube shape. The multi-tubular body may include a thread that winds around the casing insulation in one direction or in different directions.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a configuration of a multi-tube manufacturing apparatus. FIG.

The multi-tubular production apparatus surrounds the high-pressure pipe 3 and the low-pressure pipe 4 and conveys the heat insulators 31 and 41 and compresses the high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 A transferring part 10 for passing the heat insulating material 31 and 41 through the pipe 1; Pressure tube 3 and the low-pressure tube 4 which are compressed by the heat insulating materials 31 and 41 are passed through the sheath adhesion tube 2 to enclose the high-pressure tube 3 and the low- A bonding portion 20; And a coating part (30) for forming a coating layer (7) on the outer surface heat insulating material (6). In the embodiment, the compression pipe 1 and the sheath adhesion pipe 2 are successively mounted so that the transfer part 10 and the sheath adhesion part 20 are designed to operate as one device. The compression of the heat insulating material is progressed by the compression tube 1 and the progress of the wrapping of the outer casing insulator 6 by the outer casing bonding pipe 2 is performed by a series of operations.

The transfer section 10 surrounds and transfers the heat insulating materials 31 and 41 to the high pressure pipe 3 and the low pressure pipe 4 and compresses the high pressure pipe 3 and the low pressure pipe 4 surrounded by the heat insulating materials 31 and 41 And passes through the pipe (1) to compress the heat insulators (31, 41). When the heat insulating materials 31 and 41 have a certain volume and surround the high-pressure pipe 3 and the low-pressure pipe 4, the multiple-tube volume becomes large. A multi-tube body having a large outer diameter is not easy to work in an air conditioner piping. In the air conditioner piping work, the tape is wrapped around the multiple tubes to make the volume small, so that the heat insulating materials 31 and 41 are compressed too much, resulting in a problem in the heat insulating performance of the multiple tubes. In order to solve such a problem, the transfer unit 10 compresses the heat insulating materials 31 and 41 by passing the high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 through the compression pipe 1. The compression tube inner diameter determines the degree of compression of the heat insulators 31 and 41. The larger the degree of compression of the heat insulators 31 and 41, the smaller the inside diameter of the compression pipe. The degree of compression is selected from a line that does not deteriorate the heat insulating performance of the heat insulating materials 31 and 41.

Pressure tube 3 and the low-pressure tube 4 are passed through the sheath adhesion tube 2, and the high-pressure tube 3 and the low-pressure tube 4 are sealed with the external heat insulator 6, (4). The heat insulating materials 31 and 41 are wrapped with the mantle insulating material 6 to maintain the compressed state. The mantle insulator 6 is wrapped around the high-pressure pipe 3 and the low-pressure pipe 4 in which the heat insulating materials 31 and 41 are compressed in a plane so that the heat insulating materials 31 and 41 are maintained in a compressed state. The outer shell adhering portion 20 is formed by overlapping both ends of the outer surface heat insulating material 6 up and down, and applying hot air to the overlapping portion. When the outer surface heat insulating material 6 covers the compressed heat insulating materials 31 and 41, both ends of the outer surface heat insulating material 6 overlap each other and the hot air is applied to the overlapping portions. The overlapping part is melted and adhered to a certain extent by hot air. Even if the compressed heat insulating materials 31 and 41 expand, the heat insulating materials 31 and 41 are maintained in a compressed state by the adhesive force of the external heat insulating material 6. [

The coating portion 30 coating the outer surface heat insulating material 6. The coating portion 30 forms the coating layer 7 on the outer surface heat insulating material 6. The coating layer 7 is a soft resin, an ethylene vinyl acetate (EVA) or a PVC coating, and the hot air temperature is 40 to 200 DEG C, allowing the coating layer 7 to flow and shrink while adhered to multiple tubes. The coating layer 7 surrounds the outer layer insulator 6 to prevent the multi-tubular body from being torn or the outer layer insulator 6 to be peeled off. The outer surface heat insulating material 6 keeps the heat insulating materials 31 and 41 in a compressed state but is vulnerable to external scratches. The coating portion 30 forms the coating layer 7 on the outer surface heat insulating material 6 in order to prevent the outer surface insulating material 6 from being torn by the external scratches and damaging the multiple tubes. The coating part 30 applies soft resin, EVA or PVC coating to the coating layer 7, and after the coating, hot air or air is sprayed to cause the coating layer to tightly contact with the multiple tubes and to contract.

Fig. 2 is an exemplary view showing a multi-tubular body.

The multi-tubular body includes a high-pressure pipe (3) and a low-pressure pipe (4) surrounded by the heat insulators (31, 41); A multi-function pipe (5) coupled to the high-pressure pipe (3) and the low-pressure pipe (4); A cover insulator 6 surrounding the high-pressure pipe 3 and the low-pressure pipe 4; And a coating layer coating the outer surface heat insulating material 6, and the heat insulating materials 31 and 41 and the outer surface heat insulating material 6 are compressed. The multi-tubular body may be combined with the high-pressure pipe 3 surrounded by the heat insulating materials 31 and 41 and the multi-purpose pipe 5 with the low-pressure pipe 4, or only the wires may be combined to further reduce the outer diameter. The multi-tubular body compresses the heat insulating materials (31, 41) and encloses the heat insulating material (6). And the multi-tube body is coated with the mantle insulator 6.

The multi-function pipe (5) includes a communication line and an electric wire inside. The multi-purpose pipe (5) constructed in a multi-tube comprises a communication line and a wire inside. The multi-purpose pipe is used for the air conditioner piping. The multi-purpose pipe (5) is used for storing the communication line and the electric wire connecting the air conditioner and the outdoor unit. The communication line and the wire provide the line for controlling the outdoor unit and supplying power to the air conditioner. The air conditioner controls the operation of the outdoor unit, and the communication line and the wire are used as the control line. The multi-purpose pipe (5) is used to store such communication lines and wires, so that the communication lines and wires can be buried together with the high-pressure pipe (3) and the low-pressure pipe (4). (3) and the low-pressure pipe (4) are bundled into one pipe when the piping operation is performed in the air conditioner or the outdoor unit, the communication pipe, the electric wire, the high-pressure pipe (3) and the low- 4) are connected separately.

The multi-tubular body may further include a drain pipe. The water pipe is a pipe for discharging the water generated from the air conditioner to the outside. The multi-tubular body can drain water through the drain pipe including the drain pipe. The high-pressure pipe (3) and the low-pressure pipe (4) included in the multi-tube are a passage through which the refrigerant circulates between the air conditioner and the outdoor unit. Pressure refrigerant circulates through the high-pressure pipe (3), and low-pressure refrigerant circulates through the low-pressure pipe (4). The air conditioner outputs cold air to the room, and low temperature air and high temperature air meet. When cold air and warm air meet, condensation occurs and water is generated. The generated water should be discharged outdoors. A drain pipe is used to discharge the water outdoors.

The heat insulating materials 31 and 41 are compressed through the compression tube and the sheath insulating material 6 surrounds the heat insulating materials 31 and 41 compressed through the sheath adhesive pipe and the coating layer 7 is contracted by hot air. When the high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 pass through the compression pipe, the heat insulating materials 31 and 41 are compressed. At this time, the sheath adhesion tube surrounds the outer surface heat insulating material 6 with the heat insulating materials 31 and 41 compressed. The casing heat insulating material 6 covers the heat insulating materials 31 and 41 in which the heat insulating materials 31 and 41 are compressed. Thereafter, the mantle insulator 6 is coated by the coating layer 7 and the coating layer 7 is contracted by hot air or air jet. The heat insulating material includes a heat insulating material 31 surrounding the high-pressure pipe 3 and a heat insulating material 41 surrounding the low-pressure pipe 4. [ As the heat insulating materials 31 and 41, crosslinked expanded polyethylene may be used, or a rubber foaming insulating material may be used.

Both ends of the outer surface heat insulating material 6 are overlapped with each other, and hot air is applied to the overlapped portion. When the outer surface heat insulating material 6 covers the compressed heat insulating materials 31 and 41, both ends of the outer surface heat insulating material 6 overlap each other and the hot air is applied to the overlapping portions. The overlapping part is melted and adhered to a certain extent by hot air. Even if the compressed heat insulating materials 31 and 41 expand, the heat insulating materials 31 and 41 are maintained in a compressed state by the adhesive force of the external heat insulating material 6. [

The compression pipe is selected in accordance with the degree of compression of the heat insulators 31 and 41, and the sheath adhesion pipe is selected so as to cover the compressed heat insulators 31 and 41 to form the pipe outer diameter. The compression tube is used for compressing the heat insulators 31 and 41, and the inner diameter is selected according to the degree of compression of the heat insulators 31 and 41. The sheath adhesion tube is selected so as to enclose the compressed heat insulators 31, 41 to form the desired pipe outer diameter. The larger the degree of compression of the heat insulators 31 and 41, the smaller the inside diameter of the compression tube is selected. If the inner diameter of the compression pipe is too small, the heat insulating effect of the heat insulating materials 31 and 41 may be deteriorated. The inside diameter of the compression pipe can be selected in a line that does not deteriorate the heat insulating effect of the heat insulators 31 and 41. By way of example, the compressibility of the heat insulators 31 and 41 can be reduced by about 30 percent in compression.

The materials of the heat insulating materials 31 and 41 and the mantle insulating material 6 are crosslinked expanded polyethylene and the hot air temperature is 80-200 占 폚 close to the polyethylene melting temperature. The heat insulating materials 31 and 41 and the mantle insulating material 6 are crosslinked polyethylene having good heat insulating performance and the hot air temperature applied when adhering the mantle insulating material 6 is 80 to 200 占 폚.

The coating layer 7 is a soft resin, an ethylene vinyl acetate (EVA) or a PVC coating, and the hot air temperature is 40 to 200 DEG C, allowing the coating layer 7 to flow and shrink while adhered to multiple tubes. The coating layer 7 surrounds the outer layer insulator 6 to prevent the multi-tubular body from being torn or the outer layer insulator 6 to be peeled off.

3 is an exemplary view showing a multi-tube cross section.

The cross section of the multiple tubes is surrounded by the heat insulating materials 31 and 41 in the high pressure pipe 3 and the low pressure pipe 4 and the mantle insulating material 6 is wrapped in a state in which the heat insulating materials 31 and 41 are compressed. The coating layer 7 is closed on the outer side of the outer surface of the outer surface of the outer surface of the outer surface of the outer surface of the outer surface of the outer surface of the outer surface of the outer surface. Pressure tube 3 and the low-pressure tube 4 are located at the center of the multi-tube body, and the heat insulating materials 31 and 41 surround the high-pressure tube 3 and the low- The high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 are wrapped with a casing insulating material 6 and finished with a coating layer 7.

4 is an exemplary view illustrating a method for manufacturing a multi-tubular body.

The multi-tubular production apparatus controls the transport unit 10, the sheath adhesion unit 20, and the coating unit 30 to produce multiple tubes. The transfer unit 10 surrounds and transfers the heat insulating materials 31 and 41 to the high pressure pipe 3 and the low pressure pipe 4 and compresses the high pressure pipe 3 and the low pressure pipe 40 surrounded by the heat insulating materials 31 and 41 Pressure pipe 3 and the low-pressure pipe 4, in which the heat insulating materials 31 and 41 are compressed, to the outer skin adhesion pipe 2, Pressure tube 3 and the low-pressure tube 4 are wrapped with the outer casing insulator 6 and the coating section 30 forms the coating layer 7 on the outer casing insulator 6.

The multi-tubular production apparatus surrounds the high-pressure pipe 3 and the low-pressure pipe 4 and conveys the heat insulators 31 and 41 and compresses the high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 And passes through the pipe to compress the heat insulators 31 and 41. When the heat insulating materials 31 and 41 have a certain volume and surround the high-pressure pipe 3 and the low-pressure pipe 4, the multiple-tube volume becomes large. A multi-tube body having a large outer diameter is not easy to work in an air conditioner piping. In the air conditioner piping work, the tape is wrapped around the multiple tubes to make the volume small, so that the heat insulating materials 31 and 41 are compressed too much, resulting in a problem in the heat insulating performance of the multiple tubes. In order to solve such a problem, a multi-tubular manufacturing apparatus includes a high-pressure pipe 3, a low-pressure pipe 4, a wire or a multi-function pipe 5 surrounded by a heat insulating material 31 and 41, , 41). The compression tube inner diameter determines the degree of compression of the heat insulators 31 and 41. The larger the degree of compression of the heat insulators 31 and 41, the smaller the inside diameter of the compression pipe. The degree of compression is selected from a line that does not deteriorate the heat insulating performance of the heat insulating materials 31 and 41.

The multi-tubular manufacturing apparatus includes a high-pressure pipe 3 and a low-pressure pipe 4 with a heat insulating material 6 and a high-pressure pipe 3 and a low-pressure pipe 4 through which the heat insulating materials 31 and 41 are compressed, 4) and the multi-purpose pipe (5). The heat insulating materials 31 and 41 are wrapped with the mantle insulating material 6 to maintain the compressed state. The mantle insulator 6 is wrapped around the high-pressure pipe 3 and the low-pressure pipe 4 in which the heat insulating materials 31 and 41 are compressed in a plane so that the heat insulating materials 31 and 41 are maintained in a compressed state. In the multi-tubular manufacturing apparatus, both ends of the mantle insulator (6) are stacked up and down, and hot air is applied to the overlapped portions. When the outer surface heat insulating material 6 covers the compressed heat insulating materials 31 and 41, both ends of the outer surface heat insulating material 6 overlap each other and the hot air is applied to the overlapping portions. The overlapping part is melted and adhered to a certain extent by hot air. Even if the compressed heat insulating materials 31 and 41 expand, the heat insulating materials 31 and 41 are maintained in a compressed state by the adhesive force of the external heat insulating material 6. [

The multi-tubular manufacturing apparatus coats the casing insulator 6. The multi-tubular manufacturing apparatus forms a coating layer on the outer surface heat insulating material (6). The coating layer is a soft resin, EVA (Ethylene Vinyl Acetate) or PVC coating, and the hot air temperature is 40 ° C to 200 ° C, allowing the coating layer 7 to flow, allowing it to shrink while adhering to multiple tubes. The coating layer 7 surrounds the outer layer insulator 6 to prevent the multi-tubular body from being torn or the outer layer insulator 6 to be peeled off.

The multi-tubular manufacturing apparatus is a multi-tubular manufacturing apparatus in which a resin is heated to a temperature at which the resin becomes a semi-solidified state (150 ° C to 210 ° C) by coating multi-tubular bodies, and in a semi-solidified state maintaining a constant viscosity, And the resin is successively injected into a circular mold 1.2 to 1.5 times larger than the hollow through which the multi-tubular body passes, thereby forming a coating layer on the multi-tubular body, and hot air or air is sprayed on the multi-tubular body to adhere the coating layer to the multi-tubular body.

When the degree of compression of the heat insulation material is selected, the multi-tubular production apparatus applies the compression pipe 1 to the conveying unit 10 and applies the corresponding sheath adhesion pipe 2 to the sheath adhesion unit 20. When the outer diameter of the multi-tubular body is determined, the multi-tubular manufacturing apparatus selects the compression pipe 1 and the outer shell bonding pipe 2 corresponding to the determined outer diameter, and applies the same to the transfer unit 10 and the sheath adhesion unit 20, respectively. The multi-tubular manufacturing apparatus can produce multiple tubular bodies corresponding to the determined outer diameter. As the degree of compression of the heat insulation material is changed, the compression pipe 1 and the sheath adhesion pipe 2 are applied, so that multiple tubes corresponding to various outer diameters can be manufactured. Multiple tubing for a variety of external diameters can be applied to multiple hole sizes for air conditioning piping. The multi-tubular manufacturing apparatus can provide multiple tubes suitable for the pipe outer diameter required in the air-conditioning piping operation.

When the worker measures the outer diameter to be used for the indoor air conditioning pipe and transmits the outer diameter measured by the multi-pipe manufacturing device, the multi-pipe manufacturing device receives the measured outer diameter and transfers the corresponding compression pipe (1) and sheath adhesion pipe (2) 10 and the sheath adhesive portion 30 to produce a multi-tubular body. The produced multi-tubes can be transported to the house and can be installed by the operator.

In other words, it is possible to provide a multi-tube body in which the heat insulating materials 31 and 41 are compressed and wrapped by the external heat insulating material 6. [ The heat insulating materials 31 and 41 are compressed to reduce multiple tube bodies. Air conditioning piping work can be made easier than before.

The multi-function pipe (5) is advantageous in that it includes a multi-pipe body including a communication line and an electric wire inside. The multi-function pipe (5) can store a communication line or an electric wire connected between the air conditioner and the outdoor unit. Since the communication line or the wire is not exposed to the outside, the aesthetic appearance may be beautiful.

The multi-tubular body may further include a drain pipe to discharge the water through the drain pipe. The water pipe allows the water generated from the air conditioner to be discharged outdoors.

Multi-tubular bodies can only contain wires to further reduce their appearance.

The heat insulating materials 31 and 41 are compressed through the compression tube and the sheath insulating material 6 surrounds the heat insulating materials 31 and 41 compressed through the sheath adhesion tube and the coating layer 7 is contracted by hot air to make multiple tubes Can be.

The multi-tubular manufacturing apparatus is a multi-tubular manufacturing apparatus in which a resin is heated to a temperature at which the resin becomes a semi-solidified state (150 ° C to 210 ° C) by coating multi-tubular bodies, and in a semi-solidified state maintaining a constant viscosity, And the resin is successively injected into a circular mold 1.2 to 1.5 times larger than the hollow through which the multi-tubular body passes, thereby forming a coating layer on the multi-tubular body, and hot air or air is sprayed on the multi-tubular body to adhere the coating layer to the multi-tubular body. This continuous resin injection method can be applied to produce multiple tubular bodies up to several hundred meters. In the continuous resin injection method, resin is continuously injected into a circular mold to form a coating layer on multiple tubes.

Both ends of the outer surface heat insulating material 6 overlap with each other, and hot air is applied to the overlapped portions to bond the compressed heat insulating materials 31 and 41. The external heat insulating material 6 can improve the heat insulating performance of the multi-tube body.

The compression pipe is selected in accordance with the degree of compression of the heat insulators 31 and 41 and the sheath adhesion pipe is selected so as to cover the compressed heat insulators 31 and 41 so that the pipe outer diameter is formed.

The coating layer (7) can be coated on the multi-tubular body so that the multi-tubular body can be robust against external scratches and tearing.

The multi-tubular manufacturing apparatus can produce multiple tubular bodies corresponding to various outer diameters.

FIG. 5 is a view showing an example of a multi-tubular body in which a thread is wound around a shell insulator and FIG. 6 is an example of a multi-tubular body in which a thread is wound and coated without a shell insulator.

The multi-tubular production apparatus includes a high-pressure pipe 3 and a low-pressure pipe 4 surrounded by a heat insulating material 31 and 41 and a low-pressure pipe 4 through a sheath adhesion pipe 2, ). The heat insulating materials 31 and 41 and the mantle insulating material 6 are wound around the mantle insulator 6 in one direction or in different directions while crossing the seals 8 in order to maintain the compressed state. The heat insulating material 31 and 41 are compressed in a plane by the seal 8 so as to be wound on the high pressure pipe 3 and the low pressure pipe 4 so that the external heat insulators 31 and 41 Keep the compressed state. The heat insulating materials 31 and 41 and the mantle insulating material 6 are maintained in a compressed state due to the winding of the yarn 8 even if the compressed heat insulating materials 31 and 41 and the mantle insulating material 6 expand. In another embodiment, the multi-tube manufacturing apparatus can compress the heat insulating materials 31 and 41 by winding the seal 8 around the heat insulating materials 31 and 41 without using the external heat insulating material 6. [ As a method of winding the yarn 8, the multi-tubular production apparatus can be wound in the form of a twisted yarn in one yarn 8 or alternately wound in two different yarns 8 in different directions.

The multi-tubular manufacturing apparatus can adjust the rotational speed of the yarn (8) to adjust the gap in the yarn (8) and adjust the degree of compression of the multi-tubular body by adjusting the strength of the loosening of the yarn (8). When the multi-tubular body moves forward, the rotation speed of the yarn (8) is adjusted to adjust the interval of the yarn (8) and the strength of the yarn (8) to adjust the compression degree of the multi-tubular body. The seal 8 can control the degree of compression of the multiple tubes. The chamber (8) rotates around the multiple tubes in different directions and winds them around in a net shape. Or wound in one direction only in one direction.

The multi-tubular production apparatus comprises a multi-tubular body having a chamber 8 attached to a taping device and a high-pressure tube 3 surrounded by a casing insulating material 6, a low-pressure tube 4 and a wire or multi- (8) is wound around the multi-tubular body in one direction or in different directions. The conventional taping device loosens the tape to detect multiple tubes. Here, the thread (8) is loosened to wind multiple tubes. A thread 8 unwound from the taping device winds the multiple tubes.

7 is an exemplary view showing a configuration of another embodiment of a multi-tube manufacturing apparatus.

The multi-tubular production apparatus surrounds the high-pressure pipe 3 and the low-pressure pipe 4 and conveys the heat insulators 31 and 41 and compresses the high-pressure pipe 3 and the low-pressure pipe 4 surrounded by the heat insulating materials 31 and 41 A transferring part 10 for passing the heat insulating material 31 and 41 through the pipe 1; Pressure tube 3 and the low-pressure tube 4 which are compressed by the heat insulating materials 31 and 41 are passed through the sheath adhesion tube 2 to enclose the high-pressure tube 3 and the low- A bonding portion 20; A taping portion 50 that winds the insulation material 31, 41 and the outer surface heat insulating material 6 while crossing the seals 8 in different directions around the outer surface heat insulating material 6 so as to maintain the compressed state; And a coating part (30) for forming a coating layer (7) on the outer surface heat insulating material (6). In the embodiment, the compression pipe 1 and the sheath adhesion pipe 2 are successively mounted so that the transfer part 10 and the sheath adhesion part 20 are designed to operate as one device. The compression of the heat insulating material is progressed by the compression tube 1 and the progress of the wrapping of the outer casing insulator 6 by the outer casing bonding pipe 2 is performed by a series of operations. In another embodiment, the taping portion 50 is constituted by using only the sheath adhesive tube 2 in the multi-tube manufacturing apparatus, without using the compression pipe 1 and the sheath adhesion pipe 2, So that multiple tubes can be manufactured. In another embodiment, the multi-tubular body can be manufactured by winding the thread on the heat insulators 31 and 41 without using the compression pipe 1 and the sheath adhesion pipe 2.

The taping section 50 releases the seal 8 at the failure 51 to keep the heat insulating materials 31 and 41 and the mantle insulator 6 in a compressed state to seal the mantle 6 8). Or it can only be wound in one direction in one yarn. When the taping portion 50 is rotated, the thread 8 is released from the failure 51 and the thread 8 is wound on the casing insulator 6. The rotation direction of the taping section 50 is made different from each other so that the chambers 8 in different directions intersect. The taping portion 50 includes a taping device that rotates clockwise and a taping device that rotates counterclockwise. The taping device includes a rotating portion for rotating the failure 51 around the outer casing insulator 6 so as to wind the yarns of the failure 51 and the failure 51 around the yarn 8 to the outer casing insulator 6. The rotating portion includes a motor that rotates clockwise or counterclockwise, and includes gears that multiply the force of the motor. The gear includes a pinion gear which is fitted to the motor rotary shaft and a spur gear which is fitted to the multi-tubular rotary shaft and meshes with the pinion gear. The spur gear may be an internally threaded ring gear to fit into the multi-tubular rotary shaft. The ring gear is supported by the bearing to provide a rotational force to rotate the taping portion 50 around the multiple tubes. The coating portion 30 forms the coating layer 7 on the outer surface heat insulating material 6 on which the yarn 8 is wound.

8 (a) is a left side view of the taping portion 50, and FIG. 8 (b) is an example of a side view.

There are two failures 51 on the side view and one failure 51 on the left side view.

The taping portion (50) has a failure (51) in which the thread (8) is wound; A rotary shaft 57 on which the failure 51 rotates; A ceramic guide (52) for guiding the chamber (8) of the failure (51); A tension part 53 for applying tension to the yarn 8 guided by the ceramic guide 52; A guide 55 for guiding the chamber 8 having passed through the ceramic guide 52 to the ceramic nozzle 54; And a rotating part 56 wound around the multi-tubular body of the chamber 8 through the ceramic nozzle 54.

A thread 8 is wound around the failure 51 and the ceramic guide 52 guides the thread 8 of the failure 51. The tension portion (53) applies tension to the thread (8) guided by the ceramic guide (52). The guide 55 guides the chamber 8 having passed through the ceramic guide 52 to the ceramic nozzle 54. The rotating portion 56 winds the yarn 8 passing through the ceramic nozzle 54 to the multi-tube body.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

1: compression tube 2: sheathing tube
3: high pressure pipe 4: low pressure pipe
5: Multi-purpose pipe 6:
7: Coating layer 8:
10: transfer part 20:
30: Coating part 31: Insulation material
41: heat insulating material 50: taping part
51: Failure 52: Ceramic guide
53: tension part 54: ceramic nozzle
55: guide 56:
57:

Claims (16)

A multi-pipe structure for a refrigerant connecting an air conditioner and an outdoor unit,
High pressure pipes and low pressure pipes;
A heat insulating material surrounding the high-pressure pipe and the low-pressure pipe, respectively, and being compressed by the compression means;
A compressing means for compressing the heat insulating material, wherein both ends of the compressing means are overlapped and bonded;
A thread winding around the heat insulating material by rotating the mantle insulator in clockwise and counterclockwise directions which are different from each other; And
And a coating layer for coating the outer casing insulation,
Wherein the heat insulating material is compressed through a compression tube, the sheathing insulating material surrounds the heat insulating material compressed through the sheathing adhesive tube, and the coating layer is compressed with heat insulating material contracted by hot air. delete delete delete delete The method according to claim 1,
Further comprising a multi-function pipe coupled to the high-pressure pipe and the low-pressure pipe,
The multi-purpose pipe is a multi-pipe pipe in which a heat insulating material including a communication line and an electric wire is compressed. The method according to claim 1,
Further comprising a wire or a drain pipe coupled to the high-pressure pipe and the low-pressure pipe. delete delete The method according to claim 1,
Wherein the compression pipe is selected in accordance with the degree of compression of the heat insulating material, and the sheath adhesion pipe is formed by compressing the heat insulating material selected to form the pipe outer diameter by compressing the heat insulating material. The method according to claim 1,
Wherein the material of the heat insulating material and the external heat insulating material is crosslinked expanded polyethylene and the hot air temperature is a temperature of 80 to 200 DEG C close to a polyethylene melting temperature. The method according to claim 1,
Wherein the coating layer is an ethylene vinyl acetate (EVA) or a PVC coating, and the hot air temperature is 200 占 폚 wherein the heat insulating material is compressed so as to make the coating layer flowable and shrink while being in close contact with the multiple tubes. A compression section for compressing the heat insulation material in the high pressure pipe surrounded by the heat insulation material and the low pressure pipe; And
And a coating portion for coating the heat insulating material,
The compression unit
And a taping portion wound around the heat insulating material while crossing the threads in different directions,
Wherein the coating portion forms a coating layer on the heat insulating material wound on the thread,
Wherein the taping portion is a failure in which the thread is wound;
A ceramic guide for guiding the thread of failure;
A tension unit for applying tension to the yarn guided by the ceramic guide;
A guide for guiding the yarn passed through the ceramic guide to the ceramic nozzle; And
And a rotating unit that winds the yarn passing through the ceramic nozzle to the multi-
Wherein the taping portion includes a taping device that rotates clockwise and a taping device that rotates counterclockwise,
Wherein the taping device includes a rotating portion for rotating a failure around the thermal insulation so as to wind a thread of failure and failure winding the thread over the thermal insulation,
The rotation unit includes a motor rotating in a clockwise direction or a counterclockwise direction; And gears that multiply the force of the motor,
Wherein the gear includes a pinion gear fitted to the motor rotation shaft and a spur gear fitted to the multi-tube rotation shaft and meshing with the pinion gear,
The spur gear is a ring gear which is internally opened so that it can be fitted to the multi-tube rotary shaft,
Wherein the ring gear is supported by a bearing to provide a rotational force such that the taping portion rotates about the multi-tubular body. 14. The method of claim 13,
A compression unit for compressing the high-pressure pipe and the low-pressure pipe through the compression pipe and compressing the heat insulation material; And
Pressure tube and a low-pressure tube through a sheath adhesive tube, and enclosing the high-pressure tube and the low-pressure tube with a sheath insulator,
Wherein the coating portion forms a coating layer on the casing heat insulating material. delete delete

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