KR20130053947A - Heating hose - Google Patents

Abstract

PURPOSE: A heating hose is provided to easily install the heating hose in various spaces such as curved area by comprising of a flexible material. CONSTITUTION: A heating hose(1) comprises an outer tube(50), an inner tube(10), and a heating unit(30). The inner tube is arranged inside the outer tube. The inner tube forms a transfer flow path for an object. The inner tube includes a flexible member and an insulation member. The flexible member forms the transfer flow path in which the objects is transferred and is made of a soluble material. The insulation member mutually insulates a gap between the outer tube and the heating unit. The heating unit is reciprocally arranged between the outer tube and the inner tube in a longitudinal direction of the inner tube in a constant interval. The heating unit includes a first heating unit(32) and a second heating unit(34). The first heating unit and the second heating unit heat by power which is individually supplied to transfer heat to the inner tube.

Description

Heating Hose {HEATING HOSE}

The present invention relates to a heating hose, and more particularly, to a heating hose capable of maintaining a conveying object at a constant temperature.

In general, heating hoses are equipment that transfers fluid materials such as hot melts, food and beverages and paints at a constant temperature and pressure. In addition, the heating hose is a device that is placed in the semiconductor production apparatus used to transfer the residual gas.

These heating hoses connect the respective plant devices in various industrial plants, such as food and beverage manufacturing equipment and semiconductor production equipment. For example, a heating hose used in a semiconductor production apparatus is used to discharge residual gas after the process, such as a plasma deposition apparatus.

On the other hand, a conventional heating hose is disclosed in "heating hose" which is "Korean Registered Utility Model Publication No. 0422500". As shown in FIG. 1 and FIG. 2 of the above-mentioned prior art document, the prior art document forms an insulating sheet made of a silicone resin in a bar shape and constitutes a heat generating layer having a heating wire therein. Then, the heating layer is wound around the hose to manufacture a heating hose.

However, the above-mentioned prior art heating hose wraps the hose with a heating layer in which the hot wire of the single wire is disposed inside the insulating sheet, and thus, there is a problem in that the heating hose does not play a role of the heating hose when the hot wire is shorted. . In addition, the conventional heating hose has a structure that wraps the existing hose in the heat generating layer, there is a problem that the ease of installation in various spaces, such as a curved section when connecting a plurality of facilities.

Republic of Korea Utility Model Registration No. 0422500

It is an object of the present invention to provide a heating hose which improves the existing hot wire structure composed of a single hot wire.

In addition, another object of the present invention to provide a heating hose made of a flexible (flexible) material in order to improve the ease of installation in a variety of spaces, such as a curved section.

Means for solving the problems, according to the present invention, an inner tube, an inner tube disposed inside the outer tube and forming a conveying flow path of the object to be transferred, and the length of the inner tube between the outer tube and the inner tube. Heating hoses which are alternately arranged at regular intervals along the direction and including a heating element having a first heat generating portion and a second heat generating portion generated by a power source independently supplied to each other so that heat is transferred to the inner tube. Is done by.

The inner tube may include a flexible member formed of a flexible material, a flexible member provided with a flexible material, an outer surface of the flexible member, and an insulating member that mutually insulates the outer tube and the heating element. It may include.

And, preferably, the flexible member may be provided in a corrugated shape having a constant pitch along the longitudinal direction.

On the other hand, the flexible member is a first flexible portion provided in a corrugated shape having a constant pitch along the longitudinal direction, and disposed along the first flexible portion to block the transfer of the object to the pleated region of the first flexible and a plurality of It may include a second flexible portion connected by two chains.

The flexible member is preferably made of Teflon material.

On the other hand, preferably, the flexible member is made of a corrosion resistant material, and may be coated with Teflon on the inner surface forming the transfer passage.

Further, more preferably, the heating element may spirally wrap the outer surface of the inner tube along the longitudinal direction of the inner tube.

The details of other embodiments are included in the detailed description and drawings.

The effect of the heating hose according to the present invention is as follows.

First, since the heating element that transfers heat to the inner tube by dual heating wires to increase the temperature rise and temperature maintenance efficiency for the inner tube, it provides a heating hose that can improve the reliability of the product.

Second, by configuring the inner tube of the corrugated flexible member, it is possible to improve the connection convenience between the equipment in various spaces, such as curved space.

Third, the inner tube is provided with a flexible member having a corrugated shape, and a flexible member composed of a plurality of chains to block the corrugated region can be arranged to block the transfer object that can be fixed in the corrugated region. Increase the reliability and improve the reliability.

1 is a cross-sectional view of a heating hose according to a first embodiment of the present invention,
2 is a first graph showing comparative experiment data of a heating hose according to the present invention and a conventional heating hose;
3 is a second graph showing comparative experimental data of a conventional heating hose and a heating hose according to the present invention;
4 is a third graph showing comparative experiment data of a heating hose according to the present invention and a conventional heating hose;
5 is a fourth graph showing comparative experiment data of a heating hose according to the present invention and a conventional heating hose;
6 is a cross-sectional view of a heating hose according to a second embodiment of the present invention;
7 is a cross-sectional view of a heating hose according to a third embodiment of the present invention.

Hereinafter, a heating hose according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Prior to the description, the heating hose according to the present invention is composed of the first to third embodiments, and it is apparent that each embodiment is described with different reference numerals even with the same name.

On the other hand, the comparative experiment result of the heating hose according to the present invention shown in Figures 2 to 5 and the conventional heating hose, it is noted that the graph can be applied to all of the first to third embodiments.

≪ Embodiment 1 >

1 is a cross-sectional view of a heating hose according to a first embodiment of the present invention.

As shown in FIG. 1, the heating hose 1 according to the first embodiment of the present invention includes an inner tube 10, a heating element 30, and an outer tube 50. The heating hose 1 is used in industrial sites to transfer various transfer objects, such as semiconductor production lines or food and beverage production lines.

The inner tube 10 forms a conveying flow path of the conveying object. The object to be conveyed to the conveying flow path of the inner tube 10 is a variety of materials that must maintain a constant temperature, such as liquid chocolate or residual gas from semiconductor equipment. Of course, the inner tube 10 is preferably provided with a heat resistant material. The inner tube 10 includes a first inner tube 12 and a second inner tube 14.

The first inner tube 12 forms a transfer flow path of the transfer object as described above. In addition, the first inner tube 12 maintains a constant temperature by heat transfer provided from the heating element 30 disposed on the outer surface.

The second inner tube 14 surrounds the first inner tube 12. The second inner tube 14 substantially covers the heating element 30 disposed on the outer surface of the first inner tube 12 together with the first inner tube 12. The second inner tube 14 covers the first inner tube 12 and the heating element 30, and is made of an insulating material that insulates the first inner tube 12 and the heating element 30.

Next, the heating element 30 is disposed along the longitudinal direction of the inner tube 10 between the inner tube 10 and the outer tube 50 to generate heat. The heating element 30 is provided to surround the inner tube 10 to transfer the heat generated by the inner tube (10). The heating element 30 of the present invention is provided with a teflon heating wire. The heating element 30 of the present invention includes a first heat generating portion 32, a second heat generating portion 34, a first power line 36, and a second power line 38.

The first heat generating portion 32 and the second heat generating portion 34 are provided in a coil shape that spirally wraps the outer surface of the inner tube 10 along the longitudinal direction of the inner tube 10. The first heat generating portion 32 and the second heat generating portion 34 are alternately disposed along the longitudinal direction of the inner tube 10. That is, the arrangement relationship between the first heat generating part 32 and the second heat generating part 34 is a first spirally arranged when the first heat generating part 32 is helically disposed along the longitudinal direction of the inner tube 10. The second heat generating unit 34 is arranged in a spiral at intervals of the heat generating unit 32.

The first power line 36 and the second power line 38 are connected to the first heat generating unit 32 and the second heat generating unit 34, respectively. The first power line 36 and the second power line 38 independently supply power to the first heat generating unit 32 and the second heat generating unit 34. That is, the first power line 36 and the second power line 38 are independently of the first heat generating unit 32 and the second heat generating unit 32 so that the first heat generating unit 32 and the second heat generating unit 34 respectively generate heat. Power is supplied to the second heat generating unit 34.

The outer tube 50 forms the appearance of the heating hose (1). The outer tube 50 surrounds the inner tube 10 and the heating element 30 described above. The outer tube 50 includes a heat insulating member 52 and an external insulating member 54.

The heat insulating member 52 is made of a ceramic fiber material, and preserves the heat transferred to the inner tube 10 by the heating element 30. In addition, the outer insulation member 54 is disposed so that the insulation member 52 surrounds the outer surface, and insulates the heating hose (1).

Next, FIG. 2 is a first graph showing comparative experimental data of a conventional heating hose and a heating hose according to the present invention, and FIG. 3 is a second graph showing comparative experimental data of a conventional heating hose and a heating hose according to the present invention. 4 is a third graph showing comparative experimental data of a conventional heating hose and a heating hose according to the present invention, and FIG. 5 is a third graph showing comparative experimental data of a conventional heating hose and a heating hose according to the present invention. 4 graphs.

As shown in Figures 2 to 5, the results of the comparative experiment of the conventional heating hose and the heating hose 1 according to the present invention.

First, a comparison table showing a comparison experiment when using a silicon heating heating wire in a conventional heating hose and using a heating element 30 using a Teflon heating wire in the heating hose 1 according to the present invention is shown in Table 1 below. It is.

TABLE 1

Referring to Table 1 and the graph of FIG. 2, the heating hose 1 of the related art and the heating hose 1 of the present invention are raised to the same temperature until a 40 minute time elapses. However, the conventional heating hose maintains 100 degrees after 40 minutes, and the heating hose 1 according to the present invention maintains 200 degrees after 80 minutes while the temperature continues to rise even after 40 minutes. That is, the heating hose 1 according to the present invention using the heating element 30 of the Teflon material can be raised to 200 degrees unlike the conventional heating hose using the silicone heating heating wire, thereby improving the expandability of the product use. There are advantages to it.

Second, the heating element 30 having the dual heating wire, that is, the first heating portion 32 and the second heating portion 34 in the heating hose 1 and the heating hose 1 according to the present invention when using a heating wire of the conventional heating hose A comparison table showing the comparative experiments when used is shown in Table 2 below.

<Table 2>

Referring to Table 2 and the graph of FIG. 3, a conventional heating hose using a heat insulation heating wire takes 40 minutes to rise to 100 degrees and 80 minutes to rise to 200 degrees. On the other hand, the heating hose 1 according to the present invention using dual hot wires takes 20 minutes to climb to 100 degrees and 45 minutes to climb to 200 degrees. That is, the heating hose 1 according to the present invention takes about 1/2 hour to raise the temperature compared to the conventional heating hose. Thus, the heating hose 1 according to the present invention can improve the production equipment operating efficiency, by reducing the time required to rise to the required temperature.

Third, a comparison table showing a comparison experiment when a heating wire of a conventional heating hose using a heat insulation hot wire is shorted and a heating wire of the heating hose 1 according to the present invention using a dual heating wire is shorted. It is stated in

<Table 3>

Referring to <Table 3> and the graph of FIG. 4, when the heating wire is short-circuited, the heating tube of the conventional heating hose is lowered from 150 to 20 degrees while the temperature decreases after 10 minutes. . On the other hand, the heating hose 1 according to the present invention using the dual heating wire is found that the temperature is continuously maintained by the other heating wire alternately arranged when a short circuit of the heating wire, that is, any one of the heating wire short circuit occurs. Can be. Thus, the heating hose 1 according to the present invention includes a heating element 30 having a first heat generating portion 32 and a second heat generating portion 34 alternately disposed along the longitudinal direction of the inner tube (10). By doing so, there is an advantage in that the continuous temperature can be maintained even by the short circuit of any one of the first heat generating unit 32 and the second heat generating unit 34.

Fourth, on the basis of the above-described result of the 'third' comparison experiment, for the heating hose 1 according to the present invention and the heating hose 1 according to the present invention, for example, the loss amount according to the production of 100,000 won per minute is shown in Table 4 below. Stated in>

TABLE 4

Referring to <Table 4> and the graph of FIG. 5, since the heating hose of the related art that does not maintain the temperature at which the transfer object is transported in the event of a short-circuit of the hot wire is continuously lost until the product is replaced. Increases. On the other hand, the heating hose 1 according to the present invention is continuously produced by the other one even if any one of the first heating unit 32 and the second heating unit 34 is composed of a dual heating wire, thereby producing a product No loss is incurred.

Looking at the comparison result data of the first to fourth conventional heating hose as described above and the heating hose (1) according to the present invention, the heating hose (1) according to the present invention is the first heating unit 32 and the second heat generation Since the heating element 30 composed of dual heating wires of the part 34 is used, there is an advantage over the conventional heating hose in the required temperature rise and temperature maintenance.

That is, the heating hose 1 according to the present invention increases the temperature in a short time by operating the first heating unit 32 and the second heating unit 34 at the same time when the temperature required by the user. In addition, the heating hose 1 according to the present invention operates only at one of the first heat generating portion 32 and the second heat generating portion 34 when maintaining the required temperature, while maintaining the temperature and preventing unnecessary power loss. Can be. In addition, the heating hose (1) according to the present invention can operate the other heating wire when the heating wire that is operated to maintain the temperature of the first heating unit 32 and the second heating unit 34 is short-circuited To maintain the temperature.

&Lt; Embodiment 2 >

6 is a cross-sectional view of a heating hose according to a second embodiment of the present invention.

First, the heating hose 100 according to the second embodiment of the present invention, including the configuration of the first embodiment, it is noted that the comparison experiment results shown in FIGS. 2 to 5 can be obtained.

As shown in FIG. 6, the heating hose 100 according to the second embodiment of the present invention includes an inner tube 110, a heating element 130, and an outer tube 150. Heating hose 100 according to the second embodiment of the present invention is provided with a flexible material for the connection between the facilities.

The inner tube 110 of the present invention includes a flexible member 112 and the insulating member 114. The flexible member 112 forms a conveying path of the conveying object. The flexible member 112 is provided with a flexible material that can be bent by an external force. As shown in FIG. 6, the flexible member 112 of the present invention is provided in a corrugated shape having a constant pitch along the longitudinal direction. Thus, the flexible member 112 is provided in a corrugated shape having a constant pitch along the longitudinal direction and can be easily bent by an external force, thereby improving the usability of connecting the heating hose 100 between the facilities.

The flexible member 112 of the present invention is provided with a Teflon material. Alternatively, the flexible member 112 is provided of a SUS material which is a corrosion resistant material. That is, the flexible member 112 of the present invention is made of a teflon or SUS material in a corrugated shape having a constant pitch along the length direction and is flexible. Here, when the flexible member 112 is made of SUS material, the surface of the SUS material, that is, the inner surface of the flexible member 112 forming the transfer channel is coated with Teflon.

The insulating member 114 is provided to surround the flexible member 112 and the heating element 130. The insulating member 114 insulates the flexible member 112 and the heating element 130.

The heating element 130 is disposed to spirally wrap the outer surface of the flexible member 112. The heating element 130 includes a first heat generating unit 132, a second heat generating unit 134, a first power line 136, and a second power line 138. Of course, the heating element 130 is provided with a Teflon heating wire, as in the first embodiment of the present invention. The first heat generating unit 132 and the second heat generating unit 134 are alternately disposed on the outer surface of the flexible member 112. That is, the first heat generating unit 132 and the second heat generating unit 134 are arranged in parallel along the longitudinal direction of the flexible member 112. Here, the first heat generating portion 132 and the second heat generating portion 134 is preferably disposed in a spiral in the area recessed toward the transfer flow path side of the flexible member 112 having a corrugated shape. In addition, the first power line 136 and the second power line 138 are respectively separately the first heat generating unit 132 and the second heat generating unit 132 and the second heat generating unit 134 to operate independently. It is connected to the second heat generating unit 134 to supply power.

The outer tube 150 includes a heat insulating member 152 and an outer insulating member 154. The outer tube 150 forms the appearance of the heating hose (100). The heat insulating member 152 surrounds the inner tube 110 and the heating element 130 and insulates the inner tube 110 so that the temperature of the inner tube 110 is maintained. The heat insulating member 152 is made of ceramic fiber material. In addition, the outer insulation member 154 is provided to surround and insulates the outer surface of the insulation member 152 and is made of silicon material.

&Lt; Third Embodiment >

7 is a cross-sectional view of a heating hose according to a third embodiment of the present invention.

First, it is noted that the heating hose 300 according to the third embodiment of the present invention includes the configurations of the first and second embodiments and obtains the comparative experiment results shown in FIGS. 2 to 5.

As shown in FIG. 7, the heating hose 300 according to the third embodiment of the present invention includes an inner tube 310, a heating element 330, and an outer tube 350.

The inner tube 310 of the present invention includes a flexible member 312 and the insulating member 314. The flexible member 312 includes a first flexible part 312a and a second flexible part 312b.

Like the flexible member 112 of the second embodiment, the first flexible part 312a is provided in a corrugated shape having a constant pitch along the longitudinal direction. Thus, the flexible member 312 is provided in a corrugated shape having a constant pitch along the longitudinal direction can be easily bent by an external force, thereby improving the usability of connecting the heating hose 300 between the installation. In addition, the first flexible part 312a is made of teflon or SUS and has a pleat shape having a constant pitch along the longitudinal direction to have flexibility. Here, when the flexible member 312 is made of SUS material, the surface of the SUS material, that is, the inner surface of the flexible member 312 forming the transfer channel is coated with Teflon.

The second flexible part 312b is disposed along the longitudinal direction of the first flexible part 312a. The second flexible part 312b is connected to a plurality of chains and blocks the transfer object from flowing into the corrugated area of the first flexible part 312a. That is, the second flexible part 312b has a flexible property that can be bent by an external force together with the first flexible part 312a by connecting a plurality of chains. The second flexible part 312b blocks the corrugation area of the first flexible part 312a to prevent the precipitation of the powder of the residual gas or the material of the food and beverage product in the object to be transferred, thereby heating. In addition to the usability of the hose 300, the service life can be increased.

The insulating member 314 is provided to surround the flexible member 312 and the heating element 330. The insulating member 314 insulates the flexible member 312 and the heating element 330.

The heating element 330 is disposed to spirally surround the outer surface of the flexible member 312 as in the first and second embodiments. The heating element 330 includes a first heat generating unit 332, a second heat generating unit 334, a first power line 336, and a second power line 338. Of course, the heating element 330 is provided with a Teflon hot wire, as in the first and second embodiments of the present invention. In addition, the first heat generating unit 332 and the second heat generating unit 334 are alternately disposed helically on the outer surface of the flexible member 312, and the first power line 336 and the second power line 338. Are respectively connected to the first heat generating unit 332 and the second heat generating unit 334 to supply power so that the first heat generating unit 332 and the second heat generating unit 334 are operated independently.

The outer tube 350 includes a heat insulating member 352 and an external insulating member 354. The outer tube 350 forms the appearance of the heating hose (300). The heat insulating member 352 surrounds the inner tube 310 and the heating element 330 and insulates the inner tube 310 so that the temperature of the inner tube 310 is maintained. The heat insulating member 352 is made of ceramic fiber material. In addition, the outer insulation member 354 is provided to surround the outer surface of the insulation member 352 and is insulated, and is made of silicon material.

Thus, by configuring the heating element to heat transfer to the inner tube to the dual heating wire to increase the temperature rise and temperature maintenance efficiency for the inner tube, it is possible to improve the reliability of the product.

In addition, by forming the inner tube of the flexible member of the corrugated shape, it is possible to improve the connection convenience between the equipment in various spaces, such as curved space.

In addition, by providing the inner tube as a flexible member of the corrugated shape, and by placing a flexible member consisting of a plurality of chains to block the corrugated region, it is possible to block the transfer object that can be fixed in the corrugated region, thereby the product life period Increase the reliability and improve the reliability.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, . Therefore, it should be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

1, 100, 300: heating hose 10, 110, 310: inner tube
30, 130, 330: heating elements 32, 132, 332: first heating portion
34, 134, 334: second heat generating unit 36, 136, 336: first power line
38, 138, 338: second power line 50, 150, 350: outer tube
52, 152, 352: insulation member 54, 154, 354: outer insulation member
112, 312: flexible member 114, 314: insulating member
312a: first flexible part 312b: second flexible part

Claims (7)

An outer tube;
An inner tube disposed inside the outer tube and forming a conveying flow path of a conveying object;
A first heat generating unit which is alternately disposed between the outer tube and the inner tube at a predetermined interval along the longitudinal direction of the inner tube, and generates heat by a power source that is independently supplied so that heat is transferred to the inner tube; Heating hose comprising a heating element having a second heat generating portion. The method of claim 1,
The inner tube,
A flexible member which forms a conveying flow path through which the object to be conveyed is conveyed and is made of a flexible material;
And an insulating member surrounding the outer surface of the flexible member and insulated between the outer tube and the heating element. The method of claim 2,
The flexible member is a heating hose, characterized in that provided in a corrugated shape having a constant pitch along the longitudinal direction. The method of claim 2,
The flexible member,
A first flexible part provided in a corrugated shape having a constant pitch along the longitudinal direction;
The heating hose disposed along the first flexible part to block a transfer object from flowing into the corrugated area of the first flexible part and include a second flexible part connected to a plurality of chains. The method of claim 3,
The flexible member is a heating hose, characterized in that made of Teflon material The method of claim 3,
The flexible member is provided with a corrosion resistant material, the heating hose, characterized in that the inner surface forming the conveying passage is coated with Teflon. The method according to claim 1 or 2,
The heating element is a heating hose, characterized in that the spiral wrap around the outer surface of the inner tube along the longitudinal direction of the inner tube.

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