KR20100011738U - Textile dehydrating device of water jet loom - Google Patents

Abstract

The present invention, when weaving the fabric using a water jet loom, in the dehydration device for absorbing and drying the water adsorbed on the fabric, by fixing a separate pedestal on the top of the topstay secured L-shaped space between The dehydration pipe is installed in the space, but the dehydration groove configured in the dehydration pipe is in contact with the fabric bottom through the top of the pedestal and the topstay end without tension, and the dewatering pipe is made of thin material. In addition, the manufacturing cost can be reduced, and the depth of the dewatering groove is thin so that foreign substances such as various materials or oils can be prevented from sticking to the dewatering groove, thereby improving the dewatering efficiency and reducing the number of cleaning.

Description

Textile dewatering device for water jet looms {TEXTILE DEHYDRATING DEVICE OF WATER JET LOOM}

The present invention is to construct a dewatering device for dewatering the water adsorbed on the fabric when weaving the fabric using a waterjet weaving machine, the installation position of the dehydration pipe to be installed in a position that is not applied to the tension load of the fabric, The thin material allows to reduce the cost and at the same time, the depth of the dewatering groove is made thin so that foreign matters do not adhere to the inner wall, and the straightness of the dewatering pipe is improved to improve the dewatering efficiency.

In general, the fabric woven in the waterjet weaving machine is moved to the winding part in the wet state by the spray water, so that the dehydration apparatus using a dehydration pipe is necessarily used.

An example of a dehydration apparatus generally used is as shown in FIG. 4.

That is, as the inclination 2 sent from the inclination beam 15 passes through the inclination guide roller 17, the tension roller 4, the heald 3 and the body 1, the inclination 2 is carried out by the heald 3. ) Is opened, the weft yarn is infiltrated by the spray water between the inclined openings 2, and then the body 8 moves to weave the fabric 8.

The woven fabric (8) in the above is to dehydrate the water adsorbed on the fabric (8) while passing through the dehydrating pipe (7) located on the top top 12, the dehydrated fabric (8) is dehydrating pipe (7) It is guided to the friction roller (10) located directly below and then the upper and lower press rollers (9, 11) via the winding structure of the fabric winding roller (13).

In the case of the fabric dewatering device of the above configuration has the following disadvantages.

That is, as the fabric (8) passing through the dehydration pipe (7) is bent sharply to the friction roller (10) located at the bottom of the dehydration pipe (7) as a structure in which the tension hung on the fabric (8) is transmitted to the dewatering pipe (7) In order to prevent the dehydration pipe 7 from bending under tension of the fabric, the thickness of the dewatering pipe 7 should be made thick (about 6 to 8 mm), and the depth of the dewatering groove 7 'is also deepened.

As described above, if the thickness of the dewatering tube 7 is increased to withstand the tension of the fabric, the manufacturing cost increases, and as the depth of the dewatering groove 7 'is increased, the water contained in the water adsorbed on the fabric Various materials or materials are easily attached to the inner surface of the dewatering groove (7 ') to narrow the interval between the dewatering grooves (7'), so that the dehydration efficiency decreases, and the materials or materials attached to the inner surface of the dewatering groove (7 ') are frequently used. There was a problem such as cleaning.

The present invention is to solve the conventional problems, to install the dewatering pipe installation position of the waterjet loom in a position where the tension of the fabric is not transmitted to make the dewatering pipe made of a thin material to reduce the production cost, In addition, the depth of the dewatering groove can be configured to be thin to prevent the phenomenon of foreign matter such as a good material or oil to be attached to the dewatering groove to improve the dewatering efficiency as well as to reduce the number of cleaning of the dewatering groove.

As a means for solving the above problems, the present invention constitutes a fabric weaving device using a water jet weaving machine, by installing a pedestal on the top of the top stay installed between the fastener located on the front of the body and the friction roller, moving to the winding section The fabric of the high tension state is moved through the upper end of the side plate of the pedestal and the top end of the top stay, so that an L-shaped space is formed between the top stay and the pedestal side plate and the fabric, and the cylindrical dewatering in the L-shaped space. The pipe is installed, but the position of the dewatering groove configured in the dewatering pipe is to bring the bottom surface of the fabric through the pedestal and the topstay into contact with the tensionless state.

The present invention, when weaving the fabric using a water jet loom, in the dehydration device for absorbing and drying the water adsorbed on the fabric, by fixing a separate pedestal on the top of the topstay secured L-shaped space between The dehydration pipe is installed in the space, but the dehydration groove configured in the dewatering pipe is in contact with the fabric bottom through the top of the pedestal and the top stay end in a tensionless state. In addition, the manufacturing cost can be reduced, and the depth of the dewatering groove is thin so that foreign substances such as various materials or oils can be prevented from sticking to the dewatering groove, thereby improving the dewatering efficiency and reducing the number of cleaning. It works.

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

1 is a schematic configuration diagram of the fabric weaving device of the water jet loom 100 is installed in the dehydration device to be provided in the present invention, the inclination (W) sent from the inclined beam 120 is guide roller 121 and the tension roller ( The inclination (W) is opened by the opening movement of the heald (130) while passing through the heald 130 and the body 140 in sequence while being drawn out forward through 122, and the weft thread moves in between the inclined openings (W). The body 140 is then advanced to the body weaving the weft yarn to the fastball (C '), the point where the fabric begins to weave the fabric (C), the woven fabric (C) is dewatered while passing through the dehydrator The dehydrated fabric 8 is wound on the fabric winding roller 192 via the topstay 160, friction roller 110, and upper and lower press rollers 190, 191 is different from the conventional weaving device. There is no bar.

However, the technical gist of the present invention lies in the fabric dewatering device installed in the process of moving the absorbed fabric (C) toward the take-up roller (192).

The dewatering device of the present invention is fixed to the upper surface of the top stay 160 connecting the two side frame connection of the waterjet loom 100, as shown in Figure 1 by fixing the pedestal 150 as shown in the side plate 151 of the pedestal 150 The L-shaped space 180 is formed between the top stays 161 of the top stay 160, and a cylindrical dewatering pipe 170 having a dewatering groove 171 is formed in the space 180.

At this time, the position of the dehydration groove 171 configured in the dehydration pipe 170 is the end of the top plate 161 of the top stay 160, the woven fabric (C) is passed through the upper end 152 of the side plate 151 of the pedestal 150 The tension of the fabric (C) is not applied to the dehydrating pipe (170) at all by bringing the bottom surface of the fabric (C) through the (162) into the tensionless state, and all the tension of the fabric (C) is supported by the pedestal (150). And topstay 160.

As the woven fabric (C) is moved to the winding part as described above, the tension of the fabric (C) is not applied to the dehydrating pipe 170 at all, so that the thin material of about 2 to 3 mm when manufacturing the cylindrical dehydrating pipe 170 Since it can be used to be able to thin the depth of the dehydration groove 171.

In order to increase the dehydration effect of the fabric in the present invention, as shown in Figure 3, the dehydration groove 171 'is formed on the surface (bottom upper surface) of the fabric (C) via the pedestal 150 and the top stay 60 Another cylindrical dehydration pipe 170 'may be installed to make the dehydration of the fabric through the dehydration device in duplicate.

The present invention configured as described above transmits the inclination (W) from the inclined beam 120 to pass through the guide roller 121 and the tension roller 122, heald 130, body 140, the body 140 The last inclination (W) is the inclination (W) is opened by the opening movement of the heald (130), the weft weft by the injection water between the opening inclination (W), then the body 140 is advanced to the body The fabric (C) is woven by the needle movement, and the woven fabric (C) is moved to be wound on the fabric winding roller 192 as in the prior art.

However, in the present invention, the woven fabric (C) can be made more effectively dewatering the fabric by the dehydrator in the process of moving toward the winding.

That is, the fabric dewatering device to be provided in the present invention is L-shaped space 180 between the top plate 161 constituting the top stay 160 and the side plate 151 constituting the pedestal 150 as shown in the figure The dehydration pipe 170 made of a dewatering pipe 170 is positioned in the L-shaped space 180, and the dewatering groove 171 formed in the dewatering pipe 170 has a pedestal 150, an upper end portion 152, and a top stay. (160) Since the bottom surface of the fabric (C) passing through the end 162 is in a tensionless state, the tension of the fabric (C) is not transmitted to the dehydrating pipe (170) at all.

Therefore, the tension of the fabric (C) is not transmitted to the dehydration tube 170, so that the cylindrical body constituting the dehydration tube 170 can be used as a thin material of about 2 to 3mm, the cost of making the dehydration tube 170 Can be reduced.

In addition, since the thickness of the dehydration pipe 170 is thin, the depth of the dehydration groove 171 configured in the dehydration pipe 170 is also thinned by about 2 to 3 mm, so that various foreign matters, such as a good material or oil material, may be dehydrated during the fabric dewatering process. 171) It is possible to prevent the phenomenon of sticking to the inner wall, it is possible to prevent the deterioration of the dehydration efficiency due to clogging the dehydration groove 171, as well as to reduce the number of cleaning of the dehydration groove 171.

In particular, the dehydration pipe 170 is composed of a cylindrical tubular body not only maintains excellent straightness without bending or bending, but also keeps the spacing of the dehydration groove 171 constant regardless of the left and right positions, so that the pedestal 150 and the top stay ( 160 is maintained parallel to the bottom surface of the fabric (C) passing through it can be expected to dehydrate evenly across the front of the fabric.

In addition to the dehydration pipe 170 installed on the bottom surface of the fabric (C) passing between the pedestal 150 and the top stay 160 as shown in Figure 3 in addition to another dehydration pipe on the top surface of the fabric (C) (170 ') may be provided to double dehydration to the fabric (C) passing through the dehydration device, in this case can be expected good dewatering effect is effective dewatering when applied to fabrics with a large thickness of the fabric, such as double fabric You can expect.

1: Schematic configuration diagram of the fabric weaving device of the water jet loom installed the device

2: Main Components of FIG. 1

3 is a main configuration diagram of another embodiment of the present invention

4 is a schematic configuration diagram of a conventional weaving device

5: Main Components of FIG. 4

<Description of the symbols for the main parts of the drawings>

(C)-Fabric (C ')-Fabric

(W)-Slant (100)-Waterjet Loom

(120)-Tilt Beam (121)-Guide Roller

(122)-Tension Roller (130)-Heald

(140)-Body (150)-Base

(151)-Side Plate (152)-Top

(160)-Topstay (161)-Tops

(162)-End (170)-Drain Tube

(171)-Dewatering Groove (180)-Space

(190)-Upper Press Roller (191)-Lower Press Roller

(192)-Rolling Beam

Claims (3)

In constructing the water jet loom fabric dewatering device, the pedestal 150 is fixed to one end of the top plate 161 of the top stay 160 connecting the two frames of the water jet loom 100, pedestal 150 An L-shaped space 180 is formed between the side plate 151 and the top plate 161 of the top stay 160, and a dehydration pipe 170 made of a cylindrical tube is installed in the L-shaped space 180. However, the dewatering groove 171 configured in the dewatering pipe 170 is a fabric of the water jet loom, characterized in that it is configured to contact the base bottom surface of the fabric (C) passing through the pedestal 150 and the top stay 160 in a tensionless state Dewatering device. According to claim 1, Another dewatering pipe 170 'is installed on the bottom surface of the fabric (C) passing through the pedestal 150 and the top stay 160, the dewatering groove 171' of the dewatering pipe 170 ' The fabric dewatering device of the waterjet loom, characterized in that the fabric (C) is configured to be in contact with the tension-free upper surface. According to claim 1 or 2, by maintaining the thickness of the dehydration pipe 170, 170 'about 2 to 3mm, the depth of the dehydration grooves 171 (171') is configured to maintain about 2 to 3mm Waterjet loom fabric dewatering device characterized in that.

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