KR101595450B1 - Lead wire insert tube weaving machine - Google Patents

Abstract

The present invention is to provide a device for manufacturing a reinforced tube insertedly woven with a conducting wire. The device comprises: a tube forming guide unit (20) for guiding to form a woven reinforced tube (4) wherein multiple thread are twistedly woven to cover an outer circumferential surface of a tube-forming sleeve (22), and for allowing a conducting wire (6) to pass so as to be inserted into the woven reinforced tube at the same time, thereby forming a conducting wire insertedly woven reinforced tube (8), which is a reinforced tube woven by having the conducting wire (6) inserted into the tube; a pulling operation unit (30) for moving the woven reinforced tube (4) in the tube-forming sleeve (22) of the tube forming guide unit (20); a coating unit (40) for allowing the woven reinforced tube (4), which has passed through the tube forming guide unit (20) and the pulling operation unit (30), to pass the inside thereof so as to apply a coating liquid (5) to a surface of the woven reinforced tube (4); and a drying unit (50) for passing the woven reinforced tube (4) which has the coating liquid (5) applied to the surface thereof so as to dry the coating liquid (5).

Description

Technical Field [0001] The present invention relates to a lead wire insert tube weaving machine,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wire reinforcing tube manufacturing apparatus, and more particularly, to a weaving reinforcing tube manufacturing apparatus that can be manufactured such that a wire is inserted into a weave reinforcing tube while simultaneously woven. The present invention also relates to a new lead wire weaving reinforcing tube manufacturing apparatus which can form a coating layer on a lead wire weaving reinforcement tube by a continuous operation.

Generally, a lead wire such as a heater, which is connected to a heat generating element generating heat, is protected by a heat-generating body. That is, a lead wire connected to a heating element such as a heater is inserted into a weaving reinforcement tube, and a wire is connected to a heating element in a state where the wire is inserted into the weaving reinforcement tube, thereby preventing burnout such as burning of a wire by heat of the heating element do. Woven reinforcement tubes woven by these yarns are used to protect not only the wires connected to the heater but also the wires used in various other fields. For example, to protect conductors connected to the heater inside the mold, weaving reinforcement tubes may be used on the conductors, or in order to control various devices in one place by the main control unit, conductors The weft reinforcing tube is used for connecting these strands when connecting the weft reinforcement tube. The weft reinforcement tube is covered with the stranded wires connected to each other in the main control unit to prevent the twisted wires from being twisted.

At this time, a weaving reinforcement tube manufacturing apparatus is required to make a weaving reinforcement tube wrapped around the wire. The weaving reinforcement tube manufacturing apparatus makes a weaving reinforcement tube by twisting a plurality of strands of yarn. A method of making a woven reinforcing tube as described in Korean Patent Laid-Open No. 10-2013-0129603 entitled " Reinforcing tube and reinforcing tube manufacturing method in which conductor is woven is disclosed. In addition, a technique of making a tubular fiber tube by twisting a plurality of yarns such as "a weaving machine for manufacturing a tubular thread" in Korean Patent Registration No. 10-0767141 has been proposed.

On the other hand, it is necessary to form a coating layer on the surface of the woven coating tube after woven a plurality of strands of the woven reinforcing tube. The coating liquid is applied to the surface of the weaving reinforcing tube to form a coating layer. If such a coating layer is not formed, the thread of the weaving reinforcing tube is loosened and can not be used. Therefore, It is essential that a coating is applied to the substrate.

However, there is a disadvantage that the coating and coating layer drying process must be performed on the surface of the weaving reinforcement tube by a separate coating and drying apparatus after manufacturing a woven reinforcement tube separately in most of the conventional apparatuses for producing a reinforcement for a weaving reinforcement. In addition, since the process of fabricating the weaving reinforcement tube by woven yarn and the process of coating are separately performed, the installation cost of the apparatus is increased and the workability is also lowered. In addition, the space occupied by the drying furnace in the coating and drying apparatus of the woven reinforcing tube has been too large, which requires a large installation space. Conventionally, since the drying furnace is horizontally installed in the coating and drying apparatus of the woven reinforcing tube, the work space occupies a lot of space, and thus the installation space of the work space becomes very large.

Korean Patent Laid-Open No. 10-2013-0129603 (published Nov. 29, 2013) Korean Registered Patent No. 10-0251491 (registered on Jan. 12, 2000) Korean Patent Laid-Open No. 10-2014-0047410 (published Apr. 22, 2014) Domestic Registration No. 10-0502206 (Registered on Jul. 2005) Domestic Patent Registration No. 10-0767141 (Registered on October 10, 2007)

The present invention has been developed in order to solve the problems as described above, and an object of the present invention is to provide a weaving reinforcing tube which is formed by twisting a plurality of yarns The present invention relates to a wire harness reinforcing tube manufacturing apparatus having a new structure capable of simultaneously inserting wires into a weaving reinforcement tube while weaving. In particular, it is an object of the present invention to provide a new wire harness reinforcing tube manufacturing apparatus with a new structure capable of forming a coating layer on the surface of a weaving reinforcing tube by forming a wire embedding reinforcement tube in a continuous integration process.

According to the present invention, a plurality of yarns are wrapped around an outer circumferential surface of a tube forming sleeve to form a twisted weave reinforcing tube, and at the same time a wire is inserted into the weave reinforcing tube A tube forming guide part forming the wire insertion weaving reinforcing tube in which the wire is inserted into the weaving reinforcing view; A pulling operation part for moving the weaving reinforcing tube in the tube forming sleeve of the tube forming guide part; A coating unit for applying the coating liquid to the surface of the weaving reinforcing tube while passing the weaving reinforcement tube passing through the tube forming guide unit and the pulling operation unit; And a drying unit for passing the coating liquid through the weaving reinforcement tube coated on the surface to dry the coating liquid.

The tube forming guide portion is disposed at an inner position of the failure moving plate and passes through the outer peripheral surface of the weaving reinforcing tube in which a plurality of yarns are weaved and guides the inner tube to be inserted into the weaving reinforcing tube, ; And a tube guide hole disposed on the longitudinal direction of the tube forming sleeve and communicating with the upper and lower tube guide holes arranged to be spaced apart from the outer circumferential surface of the tube forming sleeve by a predetermined distance, And a pair of moving rollers disposed on the upper portion to move the weaving reinforcing tube, wherein the coating portion is disposed on the moving roller to store the coating liquid, and the weaving reinforcement tube And a coating bowl for coating the surface of the weaving reinforcing tube with the coating liquid, wherein the drying unit includes a drying furnace disposed above the moving roller of the pulling operation unit.

A main frame on which the failure transfer plate is supported; A rotating shaft rotatably supported on the main frame and disposed in a vertical direction; A horizontal rotary shaft connected to the rotary shaft through a power transmission gear and provided in the main frame; A driving roller gear supported on the main frame and disposed below the coating bowl of the coating unit; And a driven roller gear supported on the main frame and engaged with the driving roller gear, wherein the pair of moving rollers are coaxially coupled to the driving roller gear and the driven roller gear, And the guide weir is configured to raise the weaving reinforcement tube between the pair of moving rollers.

Wherein the power transmission gear comprises: a worm disposed coaxially with the vertical rotation shaft on one side of the failure transfer plate; A worm wheel coaxially provided on a shaft rotatably provided in the main frame and meshed with the worm; A power coupling drive gear coaxially provided in the shaft member; And a power connection driven gear coaxially coupled to the horizontal rotation shaft rotatably supported on the main frame and meshed with the power transmission gear.

The pair of moving rollers are disposed at positions where the outer circumferential surfaces face each other, and the outer circumferential surfaces of the moving rollers are provided with tube guide grooves extending in the circumferential direction.

A stopping plate supported on the main frame so as to be disposed on an upper portion of the coating bowl and having a tube passage hole communicated with the upper and lower surfaces thereof; And a coating liquid guide guide piece which is provided inside the coating bowl and communicates with the upper and lower portions through a lower tube passage hole fitted to the outer circumferential surface of the weaving reinforcing tube to be raised with the weaving reinforcing tube to be caught by the stopping plate .

And the upper end of the tube-forming sleeve passes between the pair of moving rollers and is further raised above the moving rollers.

Wherein the drying furnace is supported on the main frame so as to be disposed above the coating bowl and is arranged in parallel with at least two or more of the drying furnaces, and a coating barrel filled with a coating liquid is inserted in the weaving- And the coating liquid is applied to the surface of the weaving reinforcing tube at least twice as the weaving reinforcing tube is passed into the coating barrel and the coating liquid is applied to the inside of the drying furnace more than once, And then drying is carried out.

Wherein the weaving reinforcement tube further includes a guide roller passing through the drying passages through which the weaving reinforcement tube passes, and the weaving reinforcement tube is turned by the guide roller into a drying furnace other than the drying furnace immediately above the coating bowl .

A wire feeding bobbin for allowing the wire to pass through the tube forming sleeve; And a winding bobbin wound around the conductor passing through the tube forming sleeve.

Wherein the drying furnace is supported by the main frame so as to be disposed above the coating bowl and is disposed in parallel with at least two or more of the drying booths, and the winding bobbin is provided at a position next to the last drying furnace among the drying furnaces, And the winding bobbin is wound around the wire insertion weaving reinforcing tube in the last drying furnace.

The apparatus for manufacturing wire-inserted and woven reinforcing tubes according to the present invention has an effect of collectively coating the coating solution and drying the coating solution while guiding the weaving reinforcing tube to be woven by the main tube-forming guide tube unlike the conventional method.

In addition, since the weaving reinforcing tube is manufactured by woven thread and the coating process is performed at the same time, the equipment cost is lowered and the cost is improved, the workability is improved, and further productivity improvement can be expected.

In addition, the present invention can minimize the space occupied by the drying furnace by arranging it vertically in the vertical direction by utilizing the effective space of the workplace when installing the drying furnace in the coating and drying apparatus for the wire-guiding and weaving reinforcing tube. The present invention has the effect of preventing a case where a large installation space is required.

In the present invention, the coating liquid is applied to the wire-guiding weaving reinforcing tube at least twice and the drying operation is performed at least twice, thereby further improving the productivity of the wire-guiding weaving reinforcing tube.

1 is a front view schematically showing a configuration of a wire-inserting reinforcing tube manufacturing apparatus according to an embodiment of the present invention;
FIG. 2 is a front view showing an enlarged view of the structure of the coating bowl and the drying furnace,
Fig. 3 is a perspective view showing an enlarged structure of the coating bowl and the moving roller shown in Fig.
4 and 5 are perspective views schematically showing a process of coating a wire insertion weaving reinforcing tube with the coating bowl and the moving roller shown in Fig.
6 is a longitudinal sectional view schematically showing a process of coating a wire insertion weaving reinforcing tube with the coating bowl and the moving roller shown in Fig.
7 is a perspective view A of the drying furnace shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description. The same reference numerals are used for the same parts in the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected,""coupled," or "connected. &Quot;

Referring to the drawings, the apparatus for manufacturing wire-woven reinforcing tubes according to the present invention includes a tube-forming sleeve 22, which is a constituent of a tube-forming guide portion 20, is vertically arranged at a central portion of a failure- A pair of moving rollers 32 of the pulling operation portion 30 are provided on the tube forming sleeve 22 and a coating for applying the coating liquid 5 to the surface of the woven reinforcing tube 4 is provided on the moving roller 32. [ A coating bowl 42 of the coating unit 40 is installed on the main body frame 10 and the coating liquid 5 coated on the weaving reinforcement tube 4 is dried (52) are arranged on the lower surface of the substrate. In the present invention, a technique of twisting a plurality of yarns 2 (yarns) by twisting the weaving-reinforcing tube 4 into which the conductor 6 is to be inserted is not limited to a known technique such as the workbench described in the above-mentioned Korean Patent Registration No. 10-0767141 Can be adopted. That is, a plurality of circular failure holes are provided on the upper surface of the failure transfer plate 2P constituting the work table, and a plurality of failures 3 wound around the yarn 2 are formed in the failure transfer holes 2P formed in the failure transfer plate 2P. And the plurality of yarns 2 are twisted so as to wrap the surface of the tube-forming sleeve 22 to be described later, thereby forming the weaving reinforcing tube 4. Assuming that the plurality of first failures 3A move in the clockwise direction of the failure transfer plate 2P, the plurality of second failures 3B move in the counterclockwise direction of the failure transfer plate 2P, The failure 3A and the second failure 3B move to the '8' shape and at the same time the first failure 3A and the second failure 3B move in opposite directions along the failure transfer hole. The technique of forming the fiber-tube-shaped weaving reinforcing tube 4 by the movement of the first failure 3A and the second failure 3B is disclosed in Korean Registered Utility Model No. 20-0167649, Korean Registered Utility Model No. 20- 0167648, and 20-2010-0002157, which are well known in the art, so that detailed description thereof will be omitted.

The main part of the present invention is a tube forming guide portion 20, which includes a tube forming sleeve 22 and a tube guide piece 24. [

The tube forming sleeve 22 is preferably disposed in the vertical direction at the same position as the center of the failure shifting plate 2P. A vertical bar 21 is provided on a workbench provided on one side of the main frame 10 and a tube forming sleeve 22 is fixed to the vertical bar 21 to be vertically disposed. The vertical bar 21 is secured to the tube forming sleeve 22 by bolts and brackets or the tape is wound around the vertical bar 21 and the tube forming sleeve 22 to form a tube forming sleeve 22 can be fixed. The wire 6 enters and passes into the tube forming sleeve 22. At the lower end of the tube-forming sleeve 22, the lead wire 6 enters the upper end of the tube-forming sleeve 22. The main frame 10 is provided with a wire feeding portion at a position adjacent to the failure moving plate 2P provided at one side of the main frame 10 (the portion to which the wire 6 is supplied) The wire 6 is unwound and passed from the wire feeder by causing the wire 6 to be wound on the winding bobbin 18. The wire 6 is then pulled from the lower end of the tube- (6) enters into the upper end of the tube forming sleeve (22). In other words, the lead wire 6 is supplied to enter the inside of the tube-forming sleeve 22 by the lead wire provided at one side of the main frame 10. The lead wire supplying portion includes a lead wire supplying bobbin (17) on which a supporting shaft is rotatably supported by a bracket and a lead wire (6) is wound on the outer circumferential surface. The wire 6 wound on the wire feed bobbin 17 passes through the tube forming sleeve 22 and is wound by a winding bobbin 18 to be described later so that the wire 6 is continuously wound on the tube forming sleeve 22 Passing through the inside.

The tube guide piece 24 is fixed to the main frame 10. The tube guide piece 24 is formed in a plate shape. The tube guide piece 24 is provided with a tube guide hole 24H. The tube guide hole 24H passes through the upper and lower surfaces of the tube guide piece 24. The tube guide hole 24H is disposed coaxially with the tube passage hole 22H in the tube forming sleeve 22. [ The tube guide hole 24H is fitted to the outer circumferential surface of the tube forming sleeve 22. The inner diameter of the tube guide hole 24H is larger than the outer diameter of the tube forming sleeve 22. Since the inner diameter of the tube guide hole 24H is larger than the outer diameter of the tube forming sleeve 22, a space for moving the weaving reinforcement tube 4 is formed between the inner circumferential surface of the tube guide hole 24H and the outer circumferential surface of the tube- do. A plurality of strands of glass fiber thread are formed on the outer circumferential surface of the tube forming sleeve 22 by the first failure 3A and the second failure 3B on the outer peripheral surface of the tube forming sleeve 22 And the weaving reinforcing tube 4 is moved upward by the pair of the moving rollers 32 of the pulling operation portion 30 to be described later, The weaving reinforcing tube 4 is passed through the space of the weaving reinforcing tube 4 secured between the inner circumferential surface of the tube guide hole 24H of the tube forming sleeve 24 and the outer circumferential surface of the tube forming sleeve 22. That is, a plurality of yarns are woven on the outer circumferential surface of the tube-forming sleeve 22 and passed between the inner circumferential surface of the tube guide hole 24H of the tube guide piece 24 and the outer circumferential surface of the tube- A weaving reinforcing tube 4 having a hollow portion therein is formed while the weaving reinforcing tube 4 passes through the pair of moving rollers 32 continuously.

The pulling operation portion 30 is configured such that the first failure 3A and the second failure 3B are transferred in the shape of '8' along the plurality of circular failure holes provided on the upper surface of the failure transfer plate 2P A power transmission gear 16, a horizontal rotation shaft 14 provided on the main frame 10, a pair of moving rollers 32, a driving roller gear 33, and a driven roller gear 34 .

The rotating shaft 12 is rotatably coupled to the main frame 10 and disposed in a vertical direction. A gear is coaxially provided on the lower side outer circumferential surface of the rotating shaft 12 and the gear is provided with a bobbin moving operation (not shown) constituting a part of a driving device for causing movement of the first and second failures 3A, Gear (not shown). The rotating shaft 12 is connected to a motor shaft of the driving motor by a known power transmission means such as a gear, a pulley, and a belt. Therefore, when the motor shaft of the drive motor rotates, the rotation shaft 12 is rotated in a state in which it is erected in the vertical direction, and at the same time, the first failure 3A and the second failure 3B are moved. Like the conventional vertical shaft and worm 16a shaft described in the registration number 10-0767141, while the rotary shaft 12 is rotated with respect to the main frame 10 in a state in which it is erected in the vertical direction, The failure (3A) and the second failure (3B) convey the rotational driving force to move.

The power transmission gear 16 includes a worm 16a, a worm wheel 16b, a power coupling drive gear 16c, and a power coupling driven gear 16d.

The rotation shaft 12 is provided with a worm 16a coaxially disposed on the vertical rotation shaft 12. [ A worm 16a is provided on the outer circumferential surface of the upper end of the rotating shaft 12 in a state where the rotating shaft 12 is vertically disposed on one side of the failure moving plate 2P supported by the main frame 10. [

The main frame 10 is provided with a worm wheel 16b engaged with the worm 16a. A shaft member at the center of the worm wheel 16b is rotatably coupled to the main frame 10 and the worm wheel 16b is engaged with a worm 16a provided on the rotary shaft 12. [ The worm 16a and the worm wheel 16b become worm gears.

The power connection driving gear 16c is provided coaxially with a shaft member provided at the center of the worm wheel 16b. Therefore, when the worm wheel 16b is rotated, the power coupling drive gear 16c also rotates.

A horizontal rotation shaft 14 is rotatably mounted on the main frame 10 and a power connection driven gear 16d is coaxially disposed on the horizontal rotation shaft 14. And the power connection driven gear 16d is engaged with the power connection drive gear 16c. Accordingly, when the power coupling drive gear 16c is rotated, the power coupling driven gear 16d and the horizontal rotary shaft 14 rotate as well. At this time, when viewed from one side of the main frame 10, a pair of parallel intermediate connection sprockets is provided on the horizontal rotary shaft 14.

The pair of moving rollers 32 are provided on the main frame 10. A roller shaft at the center of each of the moving rollers 32 is rotatably coupled to a roller bracket provided in the main frame 10. [ The pair of moving rollers 32 is disposed below the coating bowl 42 of the coating unit 40 to be described later. On the outer peripheral surface of the moving roller 32, a tube guide groove 32G is provided. The tube guide groove 32G is a circular groove structure extending along the outer peripheral surface of the moving roller 32. [ A space is formed between the pair of moving rollers 32. [ The tube guide grooves 32G on the outer circumferential surface of each of the moving rollers 32 are disposed at positions facing each other and the space in which the weaving reinforcing tube 4 is raised between the respective tube guide grooves 32G of the moving roller 32 Respectively. The space between the pair of moving rollers 32 is disposed at a position facing the upper end portion of the tube forming sleeve 22 directly below.

A driving roller gear 33 is coaxially disposed on a roller shaft of one of the moving rollers 32 of the pair of the moving rollers 32.

The driving roller gear 33 is connected to the intermediate connecting sprocket of the horizontal rotary shaft 14 by a power transmitting means. A sprocket is provided on the roller shaft of one of the moving rollers 32 to which the driving roller gear 33 is coupled and the sprocket provided on the intermediate connecting sprocket of the horizontal rotating shaft 14 and the roller shaft of one of the moving rollers 32, . The sprocket on the drive roller gear 33 side and the intermediate connection sprocket and chain on the side of the horizontal rotation shaft 14 constitute power transmission means. When the horizontal rotation shaft 14 rotates, the driving roller gear 33 also rotates with respect to the roller bracket of the main frame 10.

A driven roller gear 34 is coaxially provided on the roller shaft of the other of the pair of the moving rollers 32. [ The driven roller gear 34 is engaged with a driving roller gear 33 provided on a roller shaft of one of the moving rollers 32. [ Accordingly, when the driving roller gear 33 rotates, the driven roller gear 34 rotates in the opposite direction, and the pair of the moving rollers 32 rotate in opposite directions. The pair of moving rollers 32 are rotated in the direction in which the weaving reinforcing tube 4 is moved upward by the space between them. That is, when viewed from the front side of the pair of moving rollers 32, the left moving roller 32 rotates counterclockwise and the right moving roller 32 rotates clockwise. Therefore, when the weaving reinforcing tube 4 enters through the space between the two moving rollers 32 and the two moving rollers 32 rotate, the outer peripheral surface of the weaving reinforcing tube 4 and each of the moving rollers 32 So that the weaving reinforcement tube 4 is lifted up by the frictional force (upward frictional force) acting between the weaving reinforcement tube 4.

At this time, when viewed from one side of the main frame 10, a pair of parallel intermediate connection sprockets are provided on the horizontal rotary shaft 14, and the drive roller gear 33 is also arranged parallel to the roller axis of one of the moving rollers 32 And two driven rollers 34 are provided in parallel to the roller axes of the other moving rollers 32 so as to engage with the two driving roller gears 33. [ That is, the pair of intermediate connection sprockets, the chain, the driving roller gear 33 and the driven roller gear 34 are arranged side by side.

The present invention is characterized in that a coating portion (40) for applying a coating liquid (5) to a surface of a weaving reinforcing tube (4) while passing a weaving reinforcement tube (4) passing through a tube forming guide portion (20) ). The coating part 40 includes a coating bowl 42 as a main component and further includes a stopping plate 43 above the coating bowl 42 and a coating liquid application guide piece 44 inside the coating bowl 42 .

The coating bowl 42 is fixed to the main bracket by a fixing means such as a bracket and a bolt, and is disposed on the pair of the moving rollers 32. From the bottom of the tube forming sleeve 22, the pair of moving rollers 32 and the coating bowl 42 to the top. The coating bowl 42 has a tube entry hole 42H at the center of the bottom surface and an upper end shape of the container. The tube passage space between the tube entry hole 42H of the coating bowl 42 and the pair of moving rollers 32 and the tube forming sleeve 22 are aligned on the same vertical line. Inside the coating bowl 42, the surface of the weaving reinforcing tube 4 is filled with a coating liquid 5 for coating. The weaving reinforcement tube 4 that comes up as the lead 6 with the conductor 6 inserted therein rises up to the tube entry hole 42H at the bottom of the coating bowl 42, The coating liquid 5 is filled into the coating layer to form a coating layer on the surface of the weaving reinforcing tube 4. [ When the woven reinforcing tube 4 and the wire 6 are lifted together, the wire 6 is inserted into the weaving reinforcing tube 4 while the tube entrance hole 42H of the coating bowl 42 is closed, The weaving reinforcement tube 4 and the wire 6 are lifted up along the tube entry hole 42H of the bowl 42 so that the coating liquid 5 is drawn into the tube entry hole 42H of the coating bowl 42 There will be no work.

The stopping plate 43 is connected to the main frame 10 by fixing means such as a bolt and a bracket. The stopping plate 43 is disposed above the coating bowl 42. The stopping plate 43 is provided with a tube passage hole 43H penetrating the upper and lower surfaces thereof. The tube passing hole 43H of the stopping plate 43 is arranged on the same vertical line as the tube entry hole 42H of the coating bowl 42. [

A coating liquid application guide member 44 is provided inside the coating bowl 42. The coating liquid application guide piece 44 is in the form of a circular block and the coating liquid application guide piece 44 is provided with a lower tube passage hole 44H to be fitted to the outer peripheral surface of the weaving reinforcing tube 4. The lower tube passage hole 44H communicates with the upper and lower surfaces of the coating liquid application guide piece 44. [ A coating liquid application guide member 44 is provided inside the coating bowl 42 and is provided below the stopping plate 43. The weaving reinforcement tube 4 raised through the bottom tube entry hole 42H of the coating bowl 42 enters the lower tube passage hole 44H at the center portion of the coating liquid application guide piece 44, And the coating liquid application guide pieces 44 are lifted up together. The coating liquid guide guide piece 44 raised with the weave reinforcing tube 4 is caught by the upper stopping plate 43 and the weft reinforcing tube 4 4 and the lead 6 only pass through the tube through hole 43H of the stopping plate 43. [

A drying furnace 52 of the drying unit 50 supported by the main frame 10 is provided above the coating liquid guide guide piece 44. The drying furnace 52 constituting the drying unit 50 is supported by the main frame 10 and disposed in a vertical direction. An inlet port through which the weaving reinforcing tube 4 into which the conductor 6 is inserted and the coating layer is applied is provided at the lower end of the drying furnace 52. At this time, the drying furnaces (52) are supported on the main frame (10) so as to be disposed above the coating bowl (42) and arranged at least two or more in parallel. In the present invention, three drying passages 52 are supported on the main frame 10 and arranged in the vertical direction.

A weaving reinforcement tube 4 rising upward from the coating bowl 42 constituting the coating portion 40 and a wire 6 inserted into the weaving reinforcement tube 4 (hereinafter referred to as a weaving reinforcement tube 4) Is inserted into the first drying furnace 52, and the wire-guiding weaving reinforcement tube 8 is inserted from underneath, as shown in Fig. When the first drying furnace 52 starts to come into contact with the first drying furnace 52A, the second drying furnace 52B is disposed next to the first drying furnace 52A and the second drying furnace 52B is disposed next to the second drying furnace 52B. 3 drying furnace 52C is disposed. The first drying furnace 52A, the second drying furnace 52B, and the third drying furnace 52C are vertically arranged and arranged side by side. The first drying furnace 52A, the second drying furnace 52B and the third drying furnace 52C are provided with openings at the upper and lower ends thereof so that the wire inserting and weaving reinforcing tube 8 can come in and out.

The first drying furnace 52A, the second drying furnace 52B and the third drying furnace 52C are provided with a heater 54. The heater 54 is constituted by a bar-shaped heater and is arranged standing up in the vertical direction. At least two bar heaters 54 are provided in the first drying furnace 52A, the second drying furnace 52B and the third drying furnace 52C with respect to the vertical center line of the drying furnaces 52, Are arranged in the radial direction.

A guide roller is provided on the main frame 10 so as to be disposed in an area adjacent to the upper end of the first drying furnace 52A and the upper end of the second drying furnace 52B. The guide roller may be referred to as a front upper guide roller 143FU. The wire insertion weaving reinforcing tube 8 coming out from the upper end of the first drying furnace 52A passes under the outer circumferential face of the front upper guide roller 143FU from the lower end of the second drying furnace 52B to the second drying furnace 52B ).

A guide roller is provided on the main frame 10 so as to be disposed in a region between the lower end of the second drying furnace 52B and the upper end of the third drying furnace 52C. The guide roller 143 may be a front lower guide roller 143FL. The wire insertion weaving reinforcing tube 8 coming out from the upper end of the second drying path 52B passes under the outer circumferential surface of the front lower guide roller 143FL from the lower end of the drying path 52B to the drying path 52B, I go inside.

A guide roller is provided on the main frame 10 so as to be disposed in an area adjacent to the upper end of the third drying furnace 52C. The guide roller 143 may be a rear upper guide roller 143RU. The wire insertion weaving reinforcing tube 8 coming out from the upper end of the second drying furnace 52B passes through the outer peripheral surface of the rear upper guide roller 143RU from the upper end of the third drying furnace 52C to the inside of the third drying furnace 52C ≪ / RTI >

At this time, a coating barrel 141 filled with a coating liquid 5 is further installed in the passage of the weaving reinforcing tube 4 between the two or more drying passages 52, (5) is applied to the surface of the weaving reinforcing tube (4) while passing through the inside of the drying furnace (141), and the coating solution (5) is coated twice or more inside the drying furnace So that drying is carried out by passing through the lead wire weaving reinforcement tube (8).

To this end, a coating barrel 141 is additionally installed on the main frame 10 so as to be disposed on the movement path between the lower ends of the first drying furnace 52A and the second drying furnace 52B. The coating barrel 141 is in the form of a container having an open upper part and is placed on a die of the main frame 10 to be placed on the movement path between the first drying furnace 52A and the lower end of the second drying furnace 52B . The main frame 10 is provided with a roller bracket and a lower guide roller 143 is rotatably mounted on the roller bracket and the lower guide roller 143 is rotatably mounted on the first drying furnace 52A and the second drying furnace The roller bracket to which the lower guide roller 143 is attached is rotatably coupled to the main frame 10 via a hinge portion so as to connect the roller bracket and the main frame 10 The roller bracket and the lower guide roller 143 are rotated upward with respect to one hinge part to install the coating barrel 141 on the die of the main frame 10, A part of the lower side of the roller bracket and a part of the lower side of the lower guide roller 143 are filled in the coating barrel 141. When the roller bracket and the lower guide roller 143 are rotated in the downward direction, The wire guide weaving reinforcement tube 8 that has descended down from the upper end of the first drying furnace 52A passes through the outer circumferential surface of the lower guide roller 143, The weaving reinforcement tube 8 is immersed in the coating solution 5 inside the weft insertion reinforcing tube 8 and is coated with the second coating solution 5 on the wire insertion weaving reinforcing tube 8.

The coating barrel 141 is supported on the main frame 10 so as to be disposed on the movement path between the second drying furnace 52B and the lower end of the third drying furnace 52C. The coating barrel 141 may also be disposed on the movement path between the second drying furnace 52B and the lower end of the third drying furnace 52C. A lower guide roller 143 is rotatably mounted on the roller bracket and another rear lower guide roller 143RL is rotatably mounted on the second drying furnace 52B The roller bracket on which the lower guide roller 143 is mounted is rotatably coupled to the main frame 10 via a hinge portion so that the roller bracket and the main frame 10, the roller bracket and the lower guide roller 143 are rotated upward to install the coating barrel 141 on the die of the main frame 10, When the roller bracket and the lower guide roller 143 are rotated downward to the original position with respect to the hinge portion connecting the frame 10, a part of the lower side of the roller bracket and a lower side part of the lower guide roller 143 are coated The wire guide weaving reinforcement tube 8 descending down from the upper end of the second drying furnace 52B passes through the outer circumferential surface of the lower guide roller 143 so as to pass through the coating liquid 5 filled in the barrel 141 The wire insertion weaving reinforcing tube 8 is immersed in the coating liquid 5 in the coating barrel 141 while being immersed therein and coated with the coating solution 5 in a tertiary order on the wire insertion weaving reinforcing tube 8. The wire insertion weaving reinforcing tube 8 coated with the coating liquid is passed from the lower side of the third drying furnace 52C to the inside of the third drying furnace 52C after passing the outer peripheral surface of the rear lower guide roller 143RL from below, I go in.

A wire insertion weaving reinforcing tube (8) is cured by passing through a wire insertion weaving reinforcing tube (8) into an inner space of the heater (54), and a wire (6) and a weaving reinforcing tube (4) 8 are formed. That is, the coating layer of the wire-guiding weaving reinforcing tube 8 is primarily dried by the heater 54 while passing through the first drying furnace 52A, and the coating solution 5 in the coating barrel 141 is secondarily dried The second coating liquid 5 is applied to the inside of the second drying furnace 52B and the second coating liquid 5 is dried. (8) enters again and the third coating liquid (5) is dried.

The main frame 10 is provided with an auxiliary guide roller 145 to be disposed at the next position of the rear upper guide roller 143RU. The wire guiding weaving reinforcing tube 8 passing through the outer peripheral surface of the rear upper guide roller 143RU passes the outer peripheral surface of the auxiliary guide roller 145. [ On the outer circumferential surface of the auxiliary guide roller 145, a plurality of guide grooves arranged in the front and back direction are provided, and the wire insertion weaving reinforcing tube 8 passes along the guide grooves. In addition, the main frame 10 is provided with a release preventing roller 146 so as to be disposed on the outer circumferential surface of the auxiliary guide roller 145. The separation preventing roller 146 prevents the lead wire weaving reinforcing tube 8 passing through the outer circumferential surface of the auxiliary guide roller 145 from deviating from the outer circumferential surface of the auxiliary guide roller 145.

If it is assumed that a lead wire supply bobbin 17 for supplying a lead wire 6 to pass the lead wire 6 into the tube forming sleeve 22 is provided at a starting point of one side of the main frame 10, A winding bobbin 18 for winding a wire 6 passing through the main frame 10 is provided at an end point of the main frame 10. That is, the drying furnaces 52 are supported on the main frame 10 so as to be disposed above the coating bowl 42, and at least two or more of them are arranged side by side. The winding bobbin 18 is provided at the next position of the drying furnace 52 disposed in the winding drum 21 so that the winding bobbin 18 is wound around the wire insertion weaving reinforcing tube 8 in the last drying furnace 52 . In the present invention, the winding bobbin 18 winds the wire 6 reinforcing tube from the third drying furnace 52C. In other words, the lead wire 6 is supplied from the lead wire supply bobbin 17 and passes through the inside of the tube forming sleeve 22 to be connected to the bottom surface inflow hole of the coating bowl 42 and a pair of moving rollers 32 and the first drying path, the second drying path 52B and the third drying path 52C and then being pulled from the tube forming sleeve 22 by being wound on the winding bobbin 18, Take it. The wire 6 is inserted into the weaving reinforcing tube 4 and the wire insertion weaving reinforcing tube 8 attached to the weaving reinforcing tube 4 by the coating layer is wound by the winding bobbin 18.

A process for manufacturing a wire-guided weaving reinforcing tube according to the present invention having the above-described structure will be summarized as follows.

First, in the initial setting of the present invention, the lead wire 6 is loosened from the lead wire bobbin 17 to pass the lead wire 6 into the tube-forming sleeve 22 and between the upper pair of the moving rollers 32 So that the wire 6 passes through the inside of the coating bowl 42 and the inside of the drying furnace 52 (that is, inside the first drying furnace 52A to the inside of the third drying furnace 52C) So that the wire 6 is partially wound on the wire 18.

Next, when the present invention is operated, the weave reinforcing tube 4 is twisted (woven) to surround the outer circumferential surface of the tube forming sleeve 22 by the movement of the first failure 3A and the second failure 3B, The wire 6 is lifted up by the space for moving the weaving reinforcing tube 4 between the outer circumferential surface of the sleeve 22 and the inner circumferential surface of the tube guide hole 24H of the tube guide piece 24, So that it can be moved upward from the inside. Since the wire 6 comes out of the upper end portion of the tube forming sleeve 22 and the weaving reinforcement tube 4 rises up from the outer circumferential surface of the tube forming sleeve 22, (6) is inserted. The conductor 6 inserted into the weaving reinforcement tube 4 may be referred to as a lead wire weaving reinforcement tube 8.

The lead wire weaving reinforcing tube 8 continues to move toward the upper coating bowl 42. A pair of moving rollers 32 provided above the tube guide piece 24 pull up the weaving reinforcing tube 4 so as to rise up through the tube passage space therebetween and at the same time by the winding bobbin 18 The weft insertion reinforcing tube 8 is passed through the tube passing space between the pair of the moving rollers 32 and is lifted up.

The wire insertion weaving reinforcing tube 8 that comes above the moving roller 32 enters into the coating bowl 42 through an inflow hole provided in the bottom surface of the coating bowl 42. In the coating bowl 42, The coating liquid 5 is applied to the surface (the outer surface as well as the inner surface) of the wire-guiding weaving reinforcing tube 8 because the reinforcing tube 5 is filled. The coating liquid 5 is supplied to the lead wire weaving reinforcing tube 8 so that the wire 6 and the weaving reinforcing tube 4 can be joined by the coating liquid 5. [ At this time, the wire insertion weaving reinforcing tube 8 is inserted into the lower tube passage hole 44H of the coating liquid application guide piece 44 provided in the coating bowl 42. In this state, the coating liquid application guide piece 44 ) And the lead wire weaving reinforcement tube (8) go up together. The boss 42a is provided on the bottom of the coating bowl 42 and the tube entrance hole 42H is provided in the inner region of the boss 42a so as to be located at the center of the coating bowl 42, And a through hole communicating with the upper and lower surfaces is provided at the center of the auxiliary guide piece 42b so that the through hole in the central portion of the auxiliary guide piece 42b is reinforced by the guide wire reinforcement 42b The tube 8 passes through and enters the bottom center tube inlet hole 42H of the coating bowl 42.

The coating liquid guide guide piece 44 is lifted up like the lead wire weaving reinforcing tube 8 and the coating liquid application guide piece 44 is stopped and stopped on the upper stopping plate 43 and the wire guide weaving reinforcing tube 8 And then goes up through the tube passing hole 43H provided in the stopping plate 43. [ The coating liquid 5 is pushed down from the outer circumferential surface of the wire-guiding weaving reinforcing tube 8 in a state where the coating liquid guide guide piece 44 is caught by the stopping plate 43 and is not raised any more. The coating liquid 5 is pushed down to prevent the coating liquid 5 from being coated on the outer circumferential surface of the wire-guiding weaving reinforcing tube 8 in a large amount.

The wire insertion weaving reinforcing tube 8 which rises up past the tube passing hole 43H of the stopping plate 43 enters the first drying furnace 52A at the lower end of the first drying furnace 52A and moves up (54). The coating liquid 5 applied to the wire-guiding weaving reinforcing tube 8 is primarily dried while passing through the first drying furnace 52A and is subjected to primary drying of the coating liquid 5 to reinforce the woven- The tube 4 is integrally joined.

The lead wire weaving reinforcement tube 8 extending from the upper end of the first drying furnace 52A passes through the outer peripheral surface of the front upper guide roller 143FU provided on the main frame 10 and the front lower guide roller 143FL, 2 drying furnace 52B. The lead wire weaving reinforcement tube 8 passes over the front upper guide roller 143FU and the wire inserting reinforcement tube 8 passes under the front lower guide roller 143FL.

A coating barrel 141 supported on the main frame 10 so as to be adjacent to a lower end of the first drying furnace 52A and a lower end of the second drying furnace 52B is provided in the coating barrel 141, ). A coating barrel 141 filled with a coating liquid 5 is provided in the passage of the wire insertion weaving reinforcing tube 8 between the first drying furnace 52A and the second drying furnace 52B. Therefore, the secondary coating liquid 5 is applied while passing the wire-guiding weaving reinforcing tube 8 into the coating barrel 141. The coating liquid 5 is applied to the lead wire weaving reinforcing tube 8 once more.

The conductor wire weaving reinforcing tube 8 coated with the secondary coating solution 5 continuously enters the second drying furnace 52B from the lower end of the second drying furnace 52B and is heated by the heater 54 And dried. The secondary coating liquid 5 applied to the wire-guiding weaving reinforcing tube 8 is subjected to secondary drying while passing through the second drying furnace 52B and the secondary drying of the coating liquid 5 The weaving reinforcing tube 4 is integrally joined.

The wire insertion weaving reinforcing tube 8 extending from the upper end of the second drying path 52B passes through the outer peripheral surface of the intermediate upper guide roller 143MU and the rear lower guide roller 143 provided on the main frame 10, 3 drying furnace 52C. The wire insertion weaving reinforcing tube 8 passes over the upper intermediate guide roller 143 and the wire insertion weaving reinforcing tube 8 passes below the rear lower guide roller 143. [

A coating barrel 141 supported on the main frame 10 is provided adjacent to the lower end of the second drying furnace 52B and the lower end of the third drying furnace 52C, ). A coating barrel 141 filled with a coating liquid 5 is provided in the passage of the wire insertion weaving reinforcing tube 8 between the second drying furnace 52B and the third drying furnace 52C. Therefore, the third coating liquid 5 is applied while passing through the wire-guiding weaving reinforcing tube 8 into the coating barrel 141. The coating solution 5 is applied to the wire-guiding weaving reinforcing tube 8 in a third order.

The conductive wire weaving reinforcing tube 8 coated with the tertiary coating solution 5 continuously enters the third drying furnace 52C from the lower end of the third drying furnace 52C and is heated by the heater 54 And dried. The tertiary coating solution 5 applied to the lead wire weaving reinforcing tube 8 is subjected to tertiary drying while passing through the third drying furnace 52C and is dried by the secondary drying of the coating solution 5, The weaving reinforcing tube 4 is integrally joined.

The wire insertion weaving reinforcing tube 8 extending from the upper end of the third drying furnace 52C is connected to the winding bobbin 18 via a rear upper guide roller 143RU provided on the main frame 10 and an auxiliary guide roller 145, .

Therefore, in the wire insertion weaving reinforcing tube manufacturing apparatus according to the present invention, the weaving reinforcement tube 4 is separately manufactured in a separate weaving reinforcement tube manufacturing apparatus, and then, on the surface of the weaving reinforcement tube 4 by a separate coating and drying apparatus, The weaving reinforcing tube 4 is formed and at the same time the conductor 6 is embedded in the weaving reinforcement tube 4 and the coating operation of the coating liquid 5 and the coating liquid The drying operation of the drying unit 5 is also effected collectively. In addition, since the weaving reinforcement tube 4 is manufactured by woven a plurality of strands of yarn and the process of coating is not carried out separately, the apparatus cost is lowered and the manufacturing cost is improved. . In addition, the present invention has an effect of preventing a case where the space occupied by the drying furnace 52 in the coating and drying apparatus of the wire-guiding and weaving reinforcing tube 8 is not too large, thereby requiring a large installation space for the apparatus. In the present invention, a plurality of drying passages 52 are installed in a vertical position, which is a work idle space, thereby preventing occupation of a large work space. As a result, the installation space of the work site is significantly reduced. And the utilization of the work space is greatly increased compared with the existing one.

In addition, in the present invention, the coating liquid 5 is applied to the wire-guiding weaving reinforcing tube 8 at least twice or more and the drying operation is performed at least twice, There is an effect to be further improved. In the present invention, in the coating bowl 42, the coating liquid 5 is coated on the wire insertion weaving reinforcing tube 8 and the coating liquid of the coating barrel 141, which is provided on the path through which the wire- Secondary and tertiary coating liquids 5 are applied in such a manner that the wire-guiding and weaving reinforcing tube 8 is passed twice through the wire-guiding reinforcement tube 5, and the primary, secondary, The first drying furnace 52A, the second drying furnace 52B and the third drying furnace 52C perform primary drying, secondary drying and tertiary drying. Therefore, the bonding strength between the wire 6 and the weaving reinforcing tube 4 in the wire-inserting weaving reinforcing tube 8 can be more firmly realized by the coating layer, so that the product reliability of the wire- .

Since the upper end of the tube forming sleeve 22 passes between the pair of the moving rollers 32 and rises above the moving rollers 32, Which is more reliable. The tube forming sleeve 22 supports a fiber-reinforced woven reinforcement tube 4 from the inside so that when the woven reinforcing tube 4 is lifted up to the space between the pair of moving rollers 32, The rising tension between the outer peripheral surface of the moving rollers 32 and the outer peripheral surface of the weaving reinforcing tube 4 becomes more reliably applied to the weaving reinforcement tube 4 by the pair of moving rollers 32, It is possible to more surely carry out the operation of moving up.

Since the coating liquid guide guide 44 provided inside the coating bowl 42 pushes down the coating liquid 5 from the outer circumferential surface of the wire guiding weave reinforcing tube 8, There is an effect that the coating liquid 5 is prevented from being applied to the outer circumferential surface unnecessarily and the coating liquid 5 is more uniformly applied to the wire inserting reinforcing tube 8 and furthermore, There is also an effect.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

2. Failure 3. Failure
3A. First failure 3B. Second failure
4. Woven reinforcement tube 5. Coating liquid
6. Lead wire 8. Lead wire insertion weaving reinforcement tube
10. Main frame 14. Horizontal rotation axis
16. Power transmission gear 16a. Warm
16b. Worm wheel 16c. Power connection drive gear
16d. Power connection driven gear 17. Lead wire supply bobbin
18. Winding bobbin 20. Tube forming guide section
22. Tube-forming sleeve 22H. Conductor passage hole
24. Tube guide piece 24H. Tube guide hole
30. Pulling operation part 32. Moving roller
32G. Tube guide groove 33. Drive roller gear
34. Follower roller gear 40. Coating part
42. Coating bowl 42H. Tube entry hole
43. Stopping plate 43H. Tube through hole
44. Coating liquid application guide piece 44H. Lower tube through hole
50. Drying section 52. Drying furnace
52A. The first drying furnace 52B. The second drying furnace
52C. Third drying furnace 54. Heater
141. Coated barrel 143FU. The front upper guide roller
143MU. Middle upper guide roller 143RU. The rear upper guide roller
143FL. Lower front guide roller 143RL. Rear lower guide roller
145. Auxiliary guide roller 146. Release roller

Claims (11)

A plurality of yarns 2 are wrapped around the outer circumferential surface of the tube forming sleeve 22 to guide the twisted weave reinforcing tube 4 to be formed and at the same time the wire 6 is inserted into the weaving reinforcing tube 4 A tube forming guide part (20) for forming a lead wire weaving reinforcing tube (8) through which the wire (6) is inserted into the weaving reinforcing view (4);
A pulling operation part (30) for moving the weaving reinforcing tube (4) in the tube forming sleeve (22) of the tube forming guide part (20);
The coating solution 5 is applied to the surface of the weaving reinforcing tube 4 while the weaving reinforcement tube 4 passing through the tube forming guide part 20 and the pulling operation part 30 passes through the inside (40);
And a drying unit (50) for allowing the coating liquid (5) to pass through the woven and reinforced tube (4) coated on the surface to dry the coating liquid (5) .
The method according to claim 1,
The tube forming guide portion 20 is formed of a plate-
The weft-reinforcing tube 4, which is arranged in an upright position at the inner side of the failure transfer plate 2P and passes through the outer peripheral surface of the weft-reinforcing tube 4 to which a plurality of yarns are weighed, is guided to be inserted into the weft- A tube-forming sleeve 22;
And a tube guide 24 disposed on the longitudinal direction of the tube forming sleeve 22 and communicating with the upper and lower tube guide holes 24H so as to be spaced apart from the outer circumferential surface of the tube forming sleeve 22 by a predetermined distance Respectively,
The pulling operation part (30) includes a pair of moving rollers (32) disposed on the tube guide piece (24) to move the weaving reinforcing tube (4)
The coating part (40)
The weaving reinforcement tube 4 is placed on the upper side of the moving roller 32 so as to store the coating liquid 5 and from the tube entrance hole 42H on the bottom side so that the coating liquid 5 is transferred to the weaving reinforcement tube 4 , And a coating bowl (42) for coating the surface of the coating bowl
Wherein the drying unit (50) comprises a drying furnace (52) disposed on the moving roller (32) of the pulling operation unit (30).
3. The method of claim 2,
A main frame 10 on which the failure transfer plate 2P is supported;
A rotation shaft (12) rotatably supported on the main frame (10) and arranged in a vertical direction;
A horizontal rotation shaft 14 connected to the rotation shaft 12 via a power transmission gear 16 and provided in the main frame 10;
A driving roller gear 33 supported by the main frame 10 and disposed below the coating bowl 42 of the coating unit 40;
And a driven roller gear (34) supported on the main frame (10) and engaged with the driving roller gear (33)
The pair of moving rollers 32 are coaxially coupled to the driving roller gear 33 and the driven roller gear 34 so as to rotate in the opposite direction so that the pair of moving rollers 32, (32) so as to raise the weaving reinforcement tube (4).
The method of claim 3,
The power transmission gear (16)
A worm 16a provided coaxially with the vertical rotation shaft 12 on one side of the failure transfer plate 2P;
A worm wheel 16b coupled to the worm 16a so as to be rotatably coupled to a central shaft member of the main frame 10;
A power coupling drive gear (16c) provided coaxially with the shaft member;
And a power connection driven gear (16d) coaxially coupled to the horizontal rotation shaft (14) rotatably supported on the main frame (10) and engaged with the power transmission gear Reinforcing tube manufacturing apparatus.
The method of claim 3,
Wherein the pair of moving rollers (32) are disposed at positions where the outer circumferential surfaces face each other, and a tube guide groove (32G) extending in the circumferential direction is provided on an outer circumferential surface of each of the moving rollers (32) Reinforcing tube manufacturing apparatus.
3. The method of claim 2,
A stopping plate 43 supported on the main frame 10 so as to be disposed above the coating bowl 42 and having a tube passage hole 43H communicated with the upper and lower surfaces thereof;
A lower tube passage hole 44H fitted to the outer peripheral surface of the weave reinforcing tube 4 is communicated with the upper and lower surfaces to be provided in the coating bowl 42 and is lifted together with the weave reinforcing tube 4, 43) of the coating liquid application guide (44).
3. The method of claim 2,
Wherein the tube-forming sleeve (22) has an upper end which is passed over the pair of moving rollers (32) and is further raised above the moving rollers (32).
3. The method of claim 2,
The drying furnace 52 is supported on the main frame 10 so as to be disposed on the upper side of the coating bowl 42 and is disposed in parallel with at least two or more drying loops 52, The weaving reinforcement tube 4 is further provided with a coating barrel 141 filled with a coating liquid 5 so that the weaving reinforcement tube 4 passes through the weaving reinforcement tube 4 So that the drying is performed by passing the coating liquid 5 through the weaving reinforcing tube 4 coated with the coating liquid 5 more than twice to the inside of the drying furnace 52 Wherein said wire reinforcing tube manufacturing apparatus is a wire reinforcing tube manufacturing apparatus.
9. The method of claim 8,
A guide roller 143 is further provided on the conveyance path of the weaving reinforcement tube 4 between the drying passages 52 through which the weaving reinforcing tube 4 passes and is guided by the guide roller 143 to the coating bowl 42 Wherein the weaving reinforcing tube (4) is turned and passed through another drying furnace (52) other than the drying furnace (52) immediately above the weaving reinforcement tube (4).
3. The method of claim 2,
A wire feed bobbin (17) for allowing the wire (6) to pass into the tube forming sleeve (22);
And a winding bobbin 18 for winding the wire 6 passing through the tube forming sleeve 22. The auxiliary guide roller 145 is separated from the auxiliary bobbin 18 at a position in front of the winding bobbin 18, And a preventive roller (146) is further provided on the inner surface of the lead wire.
11. The method of claim 10,
The drying furnace 52 is supported on the main frame 10 so as to be disposed above the coating bowl 42 and at least two or more of the drying furnaces 52 are arranged side by side,
The winding bobbin 18 is provided at the next position of the drying path 52 disposed last among the drying paths 52 and the wire insertion weaving reinforcing tube 8 is provided at the last drying path 52, And the winding bobbin (18) is wound around the winding bobbin (18).

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