KR101859624B1 - Heater hose weaved heating wire - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot-wire knitted heater hose, and more particularly, to a hot-wire knitted heater hose having a new structure in which a hot wire is woven or braided to a hose body together with glass fiber.
That is, according to the present invention, the hot wire can be bonded to the hose body at a constant interval by weaving or braiding the heat wire with the glass fiber on the hose body, and the hot wire can be connected in series to prevent malfunction of the temperature sensor during disconnection, The present invention is to provide a new structure of a hot-wire type heater hose having a structure in which woven hot-wire with glass fiber is wrapped with an insulating material and then covered with a mesh-type plastic protective cover to protect heat rays from external impacts.

Description

{Heater hose weaved heating wire}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot-wire knitted heater hose, and more particularly, to a hot-wire knitted heater hose having a new structure in which a hot wire is woven or braided to a hose body together with glass fiber.

Generally, automobile body panel assembling processes include a process of welding welding to the joints between the vehicle body panels and a process of applying a sealer to prevent leakage, rust prevention, heat dissipation and rigidity after the welding process And the like.

In the sealer application process, an automatic sealer dispenser is used which automatically discharges the sealer to the application site.

10 is a schematic view showing a sealer applying device. The sealer applying device includes a sealer feed pump 10, a filter unit 20, a booster unit 30, a spray gun unit 40, an integrated control panel 50, .

The sealer feed pump 10 is disposed in the booth 11 of a predetermined volume so as to maintain the temperature and the viscosity of the constant sealer, in order to maintain continuity of the sealer supply and easy replacement of the sealer reservoir.

The filter unit 20 functions to filter the foreign substances in the sealer discharged from the sealer supply pump 10 and adjust the sealer supply pressure to a constant level.

The booster unit 30 serves to supply or block the sealer from the filter unit 20 to the spray gun unit 40 and to seal the sealer filled in the spray gun unit 40 with the power of the servomotor, And serves to pressurize the negative side.

The spray gun unit 40 serves to coat the filled sealer on the body panel through the nozzle unit.

The integrated control panel 50 integrally controls each unit in consideration of various sealer control factors such as the temperature and flow rate of the sealer, the application timing of the sealer, and the application pattern from the sealer supply pump 10 to the application gun unit 40 It plays a role.

Particularly, the first heater hose 15 connected between the sealer feed pump 10 and the filter unit 20 and the second heater hose 25 connected between the filter unit 20 and the booster unit 30, Is applied as a heater hose including a heater and a temperature sensor for maintaining a constant viscosity of the sealer.

Thus, the operating flow of the sealer applying apparatus constructed as described above is such that the foreign matter is filtered while the sealer pumped by the sealer supply pump 10 is passed through the filter unit 20 and the step in which the foreign substance- A step of supplying the sealer to the coating gun unit 40 by the pumping force of the booster unit 30 and a step of applying the sealer to the body panel flow in the coating gun unit 40. [

At this time, the sealer which flows from the sealer feed pump 10 to the coating gun unit 40 is heated by the heater installed at each desired position in the flow path of the sealer to maintain a constant viscosity. Particularly, Even when passing through the first heater hose 15 and the second heater hose 25, a constant viscosity is maintained while being heated by a heater (not shown) built in each of the heater hoses 15 and 25. [

In addition, the temperature of the sealer is monitored in real time by sensing the temperature of the sealer at a temperature sensor (not shown) built in the heater hoses 15, 25 and transmitting the temperature to the integrated control panel.

On the other hand, the most important constituent for maintaining the viscosity of the sealer is a heater hose because if the heater hose is not provided, the sealer can not maintain a constant viscosity as it is not heated when flowing through each component.

Generally, the conventional heater hose has a structure in which a hot wire (heater wire) is spirally wound along the longitudinal direction on the outer surface of the hose body, is fixed simply by an insulating tape, and then covered with a heat insulating material.

However, the conventional heater hose has the following problems.

First, when the hot wire is wound around the hose body in a parallel manner of about 1m, if the heating wire in a specific section is disconnected, overheating in a certain region causes the sealer material in the hose to become hardened, .

That is, when the heating wire is wound around the hose body, the heating wire is connected in a parallel manner of about 1m, and even if the heating is performed by the disconnection of the heating wire in a specific section, the heating wire works normally in the remaining section, The raw material of the sealer in the sealant hardens rapidly and becomes hardened, resulting in clogging of the passage of the hose and clogging of the entire sealer passage.

Secondly, when there is no temperature sensor in the specific section and there is a temperature sensor in the remaining section, the temperature of the sealer in the remaining section can be measured, but since the temperature of the sealer flowing in the specific section can not be measured, Resulting in a malfunction result.

Third, during the sealer application operation, the movement of the booster gun combined with the robot and the movement of the robot cause the heater hose to repeatedly flow and collide with the peripheral equipment including the robot, causing damage to the heater hose , Heat short-circuit, etc.).

Fourthly, since the hot wire is wound in a spiral shape along the longitudinal direction on the outer diameter surface of the hose body and then fixed with the insulating tape, the hot wire can not be formed in an exactly uniform interval and the sealer flowing in the hose body can not be uniformly heated .

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a hose body which is made by weaving or braiding a heat wire with glass fiber, It can prevent the malfunction of the temperature sensor during disconnection. It can protect the heat ray from external impact by wrapping the heat wire woven with glass fiber with insulation and then covering it with the mesh plastic protective cover. The purpose is to provide a heater hose.

In order to accomplish the above object, the present invention provides a hose comprising: a hose body through which a fluid passes; A glass fiber and a hot wire wound around the outer surface of the hose body so as to be woven together at regular intervals; A heat insulator wrapped around the outer surface of the glass fiber and the heat wire; And a stretchable mesh-type protective cover which is covered on the outer surface of the heat insulating material; The present invention provides a hot-wire forming type heater hose.

Preferably, the hot wire is primary woven in the spiral direction with the glass fiber against the hood body shell, and the glass fiber is secondary woven in the opposite direction of the spiral.

Particularly, in order to couple the heat wires in series, the two strands of heat wire are woven at regular intervals along the longitudinal direction of the hose body, the one ends of the two strands are connected to connectors for connection with the power source side, .

Preferably, the heating wire is composed of a heating wire and a glass fiber covering body coated on the outer diameter of the heating wire.

More preferably, the heating wire is composed of a heating wire, a glass fiber covering body coated on the outer diameter of the heating wire, and Teflon coated on the surface of the glass fiber covering body.

A main temperature sensor and a sparse temperature sensor are attached at regular intervals along the longitudinal direction of the hose body in which the glass fiber and the heat wire are woven and wrapped. And is selectively connected.

Preferably, a tape for confirming the position of the sensor is attached to the surface of the heat insulating material so as to grasp the position where the main temperature sensor and the sparse temperature sensor are attached.

The mesh-type protective cover may be woven or braided in a mesh-like structure using a stretchable polyester material.

An air hose is inserted between the outer surface of the heat insulating material and the inner surface of the mesh-type protective cover to supply air pressure for driving the sealer applying device.

And a closing cap in the form of a shrink tube is fastened to both ends of the heat insulating material and the mesh type protective cover.

Through the above-mentioned means for solving the problems, the present invention provides the following effects.

First, the hot wire is woven or braided to the hose body together with the glass fiber, and the glass fiber supports the periphery of the hot wire and the periphery thereof so that not only the hot wire is bonded to the hose body at a constant interval, The spacing of the hot wires can be kept constant by the supporting force of the fibers.

Second, by connecting the hot wire in series over the entire section of the hose body, the hot wire disconnection state can be easily measured by the temperature sensor even if the hot wire is disconnected, so that the subsequent maintenance can be performed quickly, It is possible to prevent a phenomenon in which the sealer material in the hose due to over heating is hardened due to detection of a broken wire in a specific section.

 Third, the hose body woven with glass fiber and hot wire is wrapped with a heat insulating material and then covered with a mesh-type plastic protective cover having a stretching force. Thus, when the hose body is bent, the mesh plastic protective cover is expanded and protected to protect the heat ray. The impact can be buffered from being transmitted to the heat line.

Fourth, since the mesh plastic protective cover has elasticity, the air hose of the sealer application device (for example, the line supplying the air pressure to each pneumatic solenoid valve of the sealer application device) is inserted between the mesh plastic protective cover and the heat insulating material The air hose occupies a separate space in the space where the sealer application equipment is installed, and it is possible to arrange the air hoses in a complicated arrangement, and to prevent the phenomenon of interfering with the peripheral devices.

Fifth, in addition to the main temperature sensor, the sparser temperature sensor is attached at regular intervals along the longitudinal direction of the hose body woven with glass fiber and hot wire, and the connector is connected to the output line of each temperature sensor, It can be used immediately as a temperature sensor.

Sixth, by attaching a tape for sensor positioning with different colors to the surface of the heat insulating material, the tape for confirming the position of the sensor can be visually recognized through the mesh-type protective cover, and the maintenance worker can recognize the main temperature sensor and the spatter temperature It is possible to accurately identify the sensor and accurately grasp the mounted position.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing a heat wire and a glass fiber woven in a heat-
FIG. 2 is a perspective view showing a state that a hose body of a hot-wire knitted heater hose according to the present invention is covered and covered with heat rays and glass fibers;
FIG. 3 is a perspective view showing a state where a temperature sensor is mounted on a hot-wire knitted heater hose according to the present invention;
FIG. 4 is a perspective view showing a state in which a heat insulating material is covered with a hot-wire knitted heater hose according to the present invention;
FIG. 5 is a perspective view showing a state in which a temperature sensor positioning tape is attached to a surface of a heat insulating material of a hot-wire knitted heater hose according to the present invention,
FIG. 6 is a perspective view showing a state in which a mesh-type protective cover is wrapped around an outer surface of a heat insulating material of a hot-
FIG. 7A is a perspective view showing the structure including the air hose, which is a completed embodiment of the hot-wire knitted structure heater hose according to the present invention,
FIG. 7B is a perspective view showing a basic type (standard type) structure in which the heater hose according to the present invention has been manufactured,
FIG. 8 is a cross-sectional view showing a completed manufacturing process of a hot-wire knitted heater hose according to the present invention,
FIG. 9 is a perspective view showing a heat wire structure of a hot-wire knitted heater hose according to the present invention, FIG.
10 is a schematic view showing a configuration of a sealer applying device.

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

FIG. 1 is a view showing a state in which heat rays and glass fibers of a hot wire-type heater hose according to the present invention are woven; FIG. 2 is a view showing a state in which heat rays and glass fibers woven in the hose body are covered; Reference numeral 100 denotes a hose body through which a fluid to be heated flows, such as a sealer.

The hot wire 104 is fixed to the outer surface of the hose body 100 in such a manner that the hot wire 104 is woven together with the glass fiber 102.

Preferably, after the hot wire 104 is first woven together with the glass fibers 102 in the spiral direction with respect to the shell of the hose body 100, the glass fibers 102 are further woven in a direction opposite to the spiral, The hot wires 104 are spaced apart along the spiral direction on the outer surface of the hose body 100 with the glass fibers 102 interposed therebetween and the glass fibers 102 are woven in a direction intersecting the spiral direction Structure.

More specifically, the hot wire 104 and the glass fiber 102 are woven along the spiral direction with respect to the outer surface of the hose body 100 by using a conventional weaving machine, The fibers 102 are in a state of supporting the side of the heat ray 104 so that the heat rays 104 are spaced apart with the glass fiber 102 therebetween and the glass fiber 102 is again woven in the opposite direction of the spiral By covering the hot wire 104, the outer surface of the hot wire 104 is supported by the glass fiber 102 woven in the opposite direction of the spiral.

The hose body 100 may be woven with the glass fiber 102 to secure a certain distance between the hose body 100 and the hose body 100. In particular, Are supported by the glass fiber 102, so that the position of the heat ray 104 can be firmly maintained even if the heat ray 104 moves left and right.

The glass fiber 102 and the hot wire 104 are preferably directly woven on the outer surface of the hose body 100. However, It is also possible to insert the hose body 100 into the inside after woven into a cylindrical shape in advance.

The heat ray 104 is woven or braided to the hose body 100 together with the glass fiber 102 so that the glass fiber 102 supports the side surface and the outer surface of the heat ray 104, The gap of the hot wire 104 can be kept constant by the holding force and the holding force of the glass fiber 102 even when the hose body 100 is arranged in the warp arrangement as well as the hose body 100 at regular intervals.

9 (a), the heating wire 104 includes a heating wire 104-1 that generates heat by actual electrical conduction, and a heating wire 104-1 that is insulated from the outer diameter of the heating wire 104-1 And a glass fiber clad 104-2.

When the heat ray 104 is woven on the heating line 104-1 with the glass fiber cloth 104-2 so that the heat ray 104 is woven together with the glass fiber 102, The heat ray 104 and the glass fiber 102 can be more easily woven because they are glass fiber clad 104-2 that is made of the same material as the glass fiber 102. [

9B, a heating wire 104-1 for heating the heating wire 104 by actual electrical conduction and a heating wire 104-1 for heating the heating wire 104-1, When a thicker specification heat wire is required after the fiber cover 104-2 is formed or more complete insulation is required, Teflon 104-3 made of transparent material is provided on the surface of the glass fiber cover 104-2 ) Can be coated more insulatingly.

On the other hand, the hot wires 104 are bound in series across the hose body 100.

To this end, the hot wire 104 is provided in two strands so that the two strands of hot wire 104 are woven at regular intervals along the longitudinal direction of the hose body.

At this time, one end of each of the two heat wires 104 extends to the outside of the heater hose for connection to the power source side and is connected to the connector 106 (see Figs. 7 and 8) in a state exposed to the outside, As shown in the enlarged view of FIG. 2, the heat wires 104 are bound together in series.

Since the hot wire 104 is connected in series over the entire section of the hose body 100, even if the hot wire is disconnected, the hot wire disconnection state can be easily measured through the temperature sensor, so that the subsequent maintenance can be performed quickly Accordingly, it is possible to prevent the sealer material in the hose from hardening due to overheating in other sections due to the unhealthy sensing of the hot wire in a specific section of the hose when the hot wire is connected in a parallel manner.

The main temperature sensor 112 and the sparse temperature sensor 114 are attached at regular intervals along the longitudinal direction of the hose body 100 in which the glass fiber 102 and the hot wire 104 are woven, One of the power and output lines of the sensor 112 or the sparse temperature sensor 114 is selectively coupled together to the connector 106 to which the hot wire 104 is connected.

The main temperature sensor 112 and the sparser temperature sensor 114 are disposed at predetermined positions on the surface of the glass fiber 102 and the heat ray 104 woven on the outer surface of the hose body 100, Are attached at regular intervals.

At this time, the power source and the output line of the main temperature sensor 112 are connected to the connector 106 exposed to the outside of the heater hose, and the spare temperature sensor 114 is not connected to the connector 106, do.

Therefore, when the temperature of the sealer or the heat ray flowing through the inside of the hose body 100 is sensed by the main temperature sensor 112 and sent to a control panel (not shown), the temperature of the sealer temperature or the heat ray is within the normal range It is determined that the heating wire is broken or the temperature sensor is abnormal if the temperature is outside the normal range, so that subsequent maintenance measures can be taken.

If the main temperature sensor 112 is abnormal as a part of the subsequent maintenance action, the spare temperature sensor 114 which is in an unused state is used instead.

To this end, the power source and the output line of the abnormal main temperature sensor 112 are disconnected from the connector 106, and the power source of the spanner temperature sensor 114, which is a regular product not connected to the connector 106, To the connector 106, the sparse temperature sensor 114 can replace the main temperature sensor 112.

4, the heat insulating material 120 is wrapped around the outer surfaces of the glass fiber 102 and the heat wire 104 to prevent the heat generated by the hot wire from being discharged to the outside.

The heat insulating material 120 is provided in a cylindrical shape and has an inner diameter size in which the hose body 100 in which the heat ray 104 and the glass fiber 102 are woven is easily inserted.

After the hose body 100 in which the heat ray 104 and the glass fiber 102 are woven is inserted into the heat insulating material 120 and the end of the heat insulating material 120 is finished by wire tightening, The attachment of the heat insulating material 120 to the heat sink 120 is completed.

5, in order to grasp the positions where the main temperature sensor 112 and the sparse temperature sensor 114 are attached, a sensor positioning tape having different colors is formed on the surface of the heat insulating material 120. In this case, The maintenance worker can distinguish the main temperature sensor and the sparse temperature sensor and can easily grasp the mounting position of the main temperature sensor and the sparer temperature sensor so that only a part of the heat insulating material is cut out, Can be performed smoothly.

Next, a stretchable mesh-type protective cover 110 is covered on the outer surface of the heat insulating material 120.

6, after the heat ray 104 and the glass fiber 102 are woven on the outer surface of the hose body 100, the heat insulating material 120 is covered and then the outer surface of the heat insulating material 120 is stretched The hose body 100 and the heat ray 104 and the glass fiber 102 are protected by the mesh type protective cover 110 by covering with the mesh type protective cover 110. [

At this time, the mesh-type protective cover 110 is fabricated using a polyester material in a woven or braided manner so as to have a stretchable (elastic) mesh-like structure and a hollow structure.

When the hose body 100 is opened by opening the mesh-type protective cover 110 and enclosing the hose body 100 with the heat insulating material 120, the mesh-type protective cover 110 is easily adhered to the surface of the heat insulating material 120 by the elastic restoring force .

Therefore, even if an external impact acts on the hose body 100, the heat ray 104 and the glass fiber 102, the impact is relieved by the mesh-type protective cover 110, so that the hose body 100, 104 and the glass fiber 102 can be prevented from being burned.

Also, since the mesh-type protective cover 110 has a mesh-like structure and elasticity, the mesh-type protective cover 110 can be flexibly bent together even if the hose body 100 is bent.

Preferably, after covering the mesh-type protective cover 110 on the outer surface of the heat insulating material 120 as described above, a finishing cap 140, which is a kind of shrinking tube, is attached to both ends of the heat insulating material 120 and the mesh- To finish.

On the other hand, in addition to the heater hose, the sealer coating apparatus includes an air hose for supplying air pressure for driving operation to a driving section (a sealer booster and a pneumatic solenoid valve of a sealer spray gun, etc.) There is a problem in that the air hose interferes with the peripheral equipment of the sealer application apparatus.

7A and FIG. 8, the air hose 130 is inserted between the outer diameter portion of the heat insulating material 120 and the inner diameter portion of the mesh-type protective cover 110 to insert the heater hose and the air hose It is possible to realize a single line and solve the problem that the air hose interferes with the peripheral equipment of the sealer applicator.

More specifically, since the mesh-type protective cover 110 has elasticity, one side of the mesh-type protective cover 110 is opened in the outer diameter direction, and a space for inserting the air hose 130 can be easily provided, By inserting the air hose 130 between the outer diameter portion of the heat insulating material 120 and the inner diameter portion of the mesh-type protective cover 120, the heater hose and the air hose can be realized as a single line, It is possible to easily prevent the phenomenon of interference with the peripheral equipment of the application device.

7b, the heater hose according to the present invention is a standard type. The air hose 130 is installed between the outer diameter portion of the heat insulating material 120 and the inner diameter portion of the mesh-type protective cover 110 It is possible to make it possible to make it with the structure not to be inserted through.

100: Hose body
102: glass fiber
104: Heat line
104-1: Heating line
104-2: glass fiber coated body
104-3: Teflon
106: Connector
110: mesh type protective cover
112: main temperature sensor
114: Spacer temperature sensor
118: Tape for sensor positioning
120: Insulation
130: Air hose
140: Finishing cap

Claims (10)

A hose body (100) through which the fluid passes;
A glass fiber 102 and a hot wire 104 which are provided in a structure woven together at regular intervals and wrapped around the hosel body 100;
A heat insulating material 120 wrapped around the outer surfaces of the glass fibers 102 and the heat ray 104; And
A stretchable mesh-type protective cover 110 which is covered on the outer surface of the heat insulating material 120 and protects the glass fiber 102 and the heat ray 104;
And,
Wherein an air hose (130) for supplying air pressure for driving a sealer applying device is inserted between the outer surface of the heat insulating material (120) and the inner surface of the mesh protective cover (110) .
The method according to claim 1,
Wherein a heat ray (104) is primarily woven in a spiral direction with the glass fiber (102) to the outer surface of the hose body (100), and the glass fiber (102) is secondary woven in a direction opposite to the spiral direction hose.
The method according to claim 1,
Two strands of hot wire 104 are woven at regular intervals along the longitudinal direction of the hose body for the series connection of the hot wires 104. One end of each of the two hot wires 104 is connected to a connector 106) are connected to each other, and the other ends are conductively coupled.
The method according to claim 1,
Wherein the heating wire (104) comprises a heating wire (104-1) and a glass fiber covering body (104-2) coated on the outer diameter of the heating wire (104-1).
The method according to claim 1,
The heating wire 104 is provided with a heating wire 104-1, a glass fiber covering member 104-2 coated on the outer diameter of the heating wire 104-1, and a glass fiber covering member 104-2 on the surface of the glass fiber covering member 104-2 Coated teflon (104-3). ≪ RTI ID = 0.0 > 10. < / RTI >
The method according to claim 1,
The main temperature sensor 112 and the sparser temperature sensor 114 are attached at regular intervals along the longitudinal direction of the hose body 100 in which the glass fiber 102 and the hot wire 104 are woven and the main temperature sensor 112 Or the connector 106 is selectively connected to the power and output lines of the sparse temperature sensor 114. [
The method of claim 6,
And a sensor position confirming tape 118 is attached to the surface of the heat insulating material 120 to grasp the positions where the main temperature sensor 112 and the sparse temperature sensor 114 are attached. .
The method according to claim 1,
Wherein the mesh-type protective cover (110) is woven or braided in a mesh-like structure using a stretchable polyester material.
delete The method according to claim 1,
And a finishing cap (140) in the form of a shrink tube is fastened to both ends of the heat insulating material (120) and the mesh type protective cover (110).

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