KR20180000201A - Needlework Machine for High Strength Geotextile and the Geotextile - Google Patents

Abstract

The present invention relates to a geotextile sewing machine which includes a sewing device for sewing two layers of geotextile in a knitting way by comprising a hook bundle (10), a pin bundle (20), and a needle bundle (30). Two lines of holes (12a, 12b) are formed to respectively have six holes in the hook bundle (10); a hook (11) is inserted into and fixated on holes of predetermined zigzag positions; the pin bundle (20) has six pins (22) capable of adjusting the length; the pin (22) can adjust the length of protrusion respectively by a bolt (23); two lines of holes (32a, 32b) are formed to respectively have six holes in the needle bundle (30); and needles (31) are inserted into and fixated in holes of predetermined zigzag positions. The high strength geotextile mat can be manufactured to have a predetermined sewing line structure by: inserting and fixating hooks (11) into the holes of two lines (12a, 12b) formed in the hook bundle (10) along the predetermined sewing line structure; determining the protruding length of the pin (22) of the pin bundle (20) along a position of the hook (11) fixated on the hook bundle (10); and selecting a position of the needle (31) of the needle bundle (30) among the holes of the two lines (32a, 32b).

Description

Technical Field [0001] The present invention relates to a sewing machine for sewing a high strength geosynthetic mat,

The present invention relates to a sewing machine for producing a geared fiber mat. More particularly, the present invention relates to a sewing machine capable of fabricating a geosynthetical fiber mat so that a double-layer geosynthetic fiber is overlapped and sewn in a longitudinal direction so as to produce a wide geosynthetic mat.

Geosynthetics are used in dredging landfills or on soft grounds to construct roads or just formulate them. Also, geosynthetic fiber is widely used to reinforce bearing capacity in civil engineering work such as embankment slope, excavation slope, and reinforced slope.

Geosynthetic fibers are typically fabric fabrics woven with shrinkable fibers such as polyester, polypropylene, and sometimes nonwoven fabrics are also used. However, since the civil engineering area usually has a large area, the geotextiles are sewn to each other (also referred to as "suture") to expand the width of the fiber. Geosynthetic fibers are usually about 2-4 m wide, so they must be sewn to the width required for geosynthetics in a construction site that requires wide geosynthetics.

A sewing machine for sewing geosynthetic fibers against each other to produce a wide geosynthetic fiber has already been developed and used. FIG. 1 shows a geotextile mat showing a stitched state by a sewing machine which has been widely used up to now.

So far, the geotextile sewing machine has sewed two fabrics with overlapping two layers of geosynthetic fibers through four to six rows of stitched pieces. Even if the two layers of geosynthetics are overlapped and 4 to 6 rows are stitched, the strength of the stitched portion is not strong enough. The geosynthetic fiber should be installed on the construction site such as the soft ground, the reinforcing material such as gravel or soil should be put on it, and the equipment should be used such as forklane. do. Therefore, it has been a very important study in the field of geosynthetic mat to manufacture geosynthetic mat with high strength by solving these drawbacks.

In order to solve this problem, the fibers of the suture portion were overlapped twice or three times, and then the two adjacent geosynthetic fibers were stitched. However, this operation is not easy because the work speed is very slow and the seam part becomes thick.

In order to solve the above-mentioned problem of the conventional sewing machine, Japanese Laid-Open Patent Application No. 2011-23589 discloses a geotextile mat having a structure in which a plurality of geosynthetic fibers are laminated using a velcro or a zipper. However, such a sewing method is still inadequate for complicated work processes and sufficient strength.

In addition, Japanese Patent Laid-Open Publication No. 2016-13727 discloses a sewing machine in which six sewing machines stitched in the conventional 4th to 6th rows and six other sewing machines arranged in parallel are displaced little by little so that the sewing lines are formed in a diagonal direction To a sewing machine. This sewing apparatus was improved in that the sewing line was formed in an oblique direction to improve the strength of the geosynthetic mat, but since the six sewing machines were arranged, the apparatus was not easily manufactured and operated.

The present inventor has come to develop a sewing machine of the present invention capable of sewing a geosynthetical mat having a sufficiently high strength by modifying a conventional sewing machine for a geosynthetics mats.

An object of the present invention is to provide a new sewing machine for sewing a high strength geosynthetic mat.

Another object of the present invention is to provide a sewing machine capable of manufacturing a high strength geosynthetic mat while maintaining the same working efficiency as a conventional sewing machine.

It is still another object of the present invention to provide a high strength geosynthetic mat having a sufficiently high strength of the seam portion of two superposed geosynthetics.

These and other objects of the present invention can be achieved by the present invention described in detail below.

The present invention provides a sewing machine for a geosynthetic fiber, which comprises a hooking unit (10), a pin bundle (20) and a needle bundle (30) and sealing a double layer of geosynthetics by a knitting method, And the pin bundle 20 is inserted into and fixed to the hole of the predetermined zigzag position so that the length of the pin bundle 20 can be adjusted to six And the pins 22 are each capable of adjusting the protruding length by means of bolts 23 and the needle bundle 30 has two rows of holes 32a and 32b each having six holes, And the needle 31 is inserted and fixed in the predetermined zigzag position hole.

The hooks 11 are inserted and fixed in the holes of the two rows 12a and 12b formed in the hooks 10 according to the predetermined seam line structure and the hooks 11 are fixed to the hooks 11 by the position of the hooks 11 fixed to the hooks 10, The protruding length of the pin 22 of the pin bundle 20 is determined and the position of the needle 31 of the needle bundle 30 is selected from the holes of the two rows 32a and 32b, Geotechnical fiber mats can be produced.

The pin 22 can adjust the protruding length by the respective bolts 23.

A thread guide hole 34a corresponding to the six holes 32a of the needle bundle 30 is formed at the corner and a thread guide groove 34b corresponding to the six holes 32b is formed at the corner.

The hook bundle 10 moves in the forward and backward directions and the pin bundle 20 moves in the left and right direction and the needle bundle 30 moves in the vertical direction so that the three strands of the suture are knitted in a double- Suture the fibers.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

It is an object of the present invention to provide a sewing machine capable of manufacturing a high strength geosynthetical mat while maintaining the same working efficiency as a conventional sewing machine and also to provide a sewing machine capable of producing a high strength geosynthetics mat The present invention provides the effect of the invention.

FIG. 1 is a view schematically showing a sealing portion of a ground fiber mat sewn by a conventional sewing machine, wherein (A) is a plan view and (B) is a bottom view.
FIG. 2 is a view schematically showing a sealing portion of a geotextile mat sewn by a sewing machine according to the present invention, wherein (A) is a plan view and (B) is a bottom view.
FIG. 3 is a schematic exploded perspective view of a sewing machine used in a sewing machine for a conventional geared machine.
FIG. 4 is a schematic exploded perspective view of a sewing apparatus used in a sewing machine for a geosynthetic mat according to the present invention.
FIG. 5 is a schematic view of a conventional sewing line of the geoscientific mats.
FIG. 6 is a model drawing of various seams of the geosynthetic mat according to the present invention. (A) is a 6-line zigzag type, (B) is a 6-line left and right 2-line zigzag type, (C) is a 5-line zigzag type, (D) is a 5-line lower 3-line zigzag type, , And (F) are four-line, two-line zigzag type.

The present invention relates to a sewing machine capable of fabricating a geosynthetic mat so that the sewn portion has a sufficient strength by overlapping two layers of geosynthetic fibers in a longitudinal direction so as to produce a wide geosynthetic mat, High strength geosynthetic mat.

FIG. 1 is a view schematically showing a sealing portion of a ground fiber mat sewn by a conventional sewing machine, wherein (A) is a plan view and (B) is a bottom view. The conventional geotextile mats shown in Fig. 1 show that they are sealed with 6 rows of seams. Conventional geotextile mats are usually sealed with a suture line of 4 to 6 rows to seal two layers of geosynthetic fibers. In the conventional sewing machine, the geotextile mat is sewn by knitting using three strands (sutures). Thus, the plane of the mat looks like one strand as in the first figure, but the back of the mat shows three strands of suture as in figure 1 (B). Which can be easily understood by those skilled in the art.

A feature of a conventional geared fiber mat is that the seams are sewn on the same weft so that the seams are sewn parallel to the same weft, as shown in FIG. When the seams are parallel to each other, the seams are sewn on the same weft, so that when the geosynthetic fibers are stretched in the transverse direction, their strength is weakened because of their weak supporting force. These drawbacks are inevitable in the structure of the sealing device.

FIG. 3 is a schematic exploded perspective view of a sewing machine used in a sewing machine for a conventional geared machine. As shown in FIG. 3, the sewing apparatus used in the sewing machine for a geosynthetic fiber mat is composed of a bundle of claws 10, a fin bundle 20 and a bundle of needles 30, do.

The claw bundle 10 has six holes 12 arranged in a row, and hooks 11 are inserted and fixed to the respective base 12. The hook 11 serves as a needle nose for threading the knitting. The hook bundle 10 to which the hook 11 is fixed acts like a needle bar while moving back and forth.

In the pin bundle 20, six pins 21 are integrally formed. The pin bundle acts as a hole to move the thread from knitting while moving left and right. Since the six pins 21 are integrally formed in the pin bundle 20, if one of the pins is cut off, the entire pin bundle must be exchanged. In the sewing machine, the pin bundle (20) is placed on the claw bundle (10) and the needle bundle (30) is placed on the pin bundle.

As shown in FIG. 3, the needle bundle 30 has six holes 32 arranged in a line, and a needle 31 is inserted and fixed in the hole. The needle bundle 30 shown in FIG. 3 shows an inverted state for easy understanding, and actually the needle 31 is directed downward. The needle bundle 30 is assembled to the main body of the sewing machine by the engaging member 35, and the geosynthetic fibers are sewn by the knitting method while moving up and down. Six thread guide holes 33 are formed in the needle bundle 30 so as to correspond to the respective holes 32, i.e., the respective needles 31, so that the thread passes through.

The hook bundle 10 acts as a needle nose for moving the yarn in the knitting process by moving back and forth. The pin bundle 20 serves as a hole for releasing the yarn from the knitting while moving left and right. 30 are vertically moving and sewing the geosynthetics with a knitting method are well known in the art and can be easily understood by those skilled in the art to which the present invention belongs.

In the present invention, in order to solve the drawback that the strength of the conventional geosynthetical mat is weakened due to weak supporting force when the seamed fiber is stretched in the transverse direction on the same weft, the seam line is not parallel but sealed with oblique lines, As a result of studying a conventional sealing apparatus so that a strong supporting force can be maintained when the fibers are stretched in the transverse direction, a sealing apparatus having a novel structure of the present invention has been developed.

FIG. 2 is a view schematically showing a sealing portion of a geotextile mat sewn by a sewing machine according to the present invention, wherein (A) is a plan view and (B) is a bottom view. As shown in FIG. 2, a strong supporting force can be maintained when the geosynthetic fibers are stretched in the transverse direction by sewing the seams so that the seams are not located on the same weft by the diagonal lines or by various combinations.

FIG. 4 is a schematic exploded perspective view of a sewing apparatus used in a sewing machine for a geosynthetic mat according to the present invention. The claw bundle 10 is formed with two rows of holes 12a and 12b each having six holes, and the claws 11 are inserted and fixed to the holes in the predetermined zigzag position. In other words, in the hook bundle 10 of the present invention, two rows of holes 12a and 12b having six holes are formed, and the hooks 11 are fixed while alternating the front and back rows. The hooks 11 can not be fixed to the holes of the front and rear lines at the same time.

The pin bundle 20 of the present invention has six pins 22 whose lengths can be adjusted. The pins 22 can adjust the protruding length by bolts 23, respectively. The length of the pin 22 corresponds to the position of the hook 11 fixed to the hook bundle 10. That is, when the hook 11 is fixed to the front row 12a of the hole, the pin 22 is shortly fixed and when the hook 11 is fixed to the rear row 12b of the hole, the pin 22 is fixed long.

The needle bundle 30 is formed with two rows of holes 32a and 32b each having six holes and is characterized in that the needle 31 is inserted and fixed in a hole in a predetermined zigzag position. The position of the needle 31 corresponds to the position of the hook 11 fixed to the hook bundle 10 and the length of the pin 22. When the hook 11 is fixed to the front row 12a of the hole and the needle 31 is fixed to the front row 32b and the hook 11 is fixed to the rear row 12b of the hole, (32a).

A thread guide hole 34a corresponding to the six holes 32a of the needle bundle 30 is formed at the corner and a thread guide groove 34b corresponding to the six holes 32b is formed at the corner.

The hooks 11 are inserted and fixed in the holes of the two rows 12a and 12b formed in the hooks 10 according to the predetermined seam line structure and the hooks 11 are fixed to the hooks 11 by the position of the hooks 11 fixed to the hooks 10, The protruding length of the pin 22 of the pin bundle 20 is determined and the position of the needle 31 of the needle bundle 30 is selected from the holes of the two rows 32a and 32b, Geotechnical fiber mats can be produced.

The hook bundle 10 moves in the forward and backward directions and the pin bundle 20 moves in the left and right direction and the needle bundle 30 moves in the vertical direction so that the three strands of the suture are knitted in a double- Suture the fibers.

Conventional geotextile mats are sewn in parallel on the same weft. (This is also referred to as '11-shaped suture ') FIG. 5 is a schematic view of a conventional suture line of a geosynthetic mat. As in the fifth aspect, since the conventional geosynthetic fiber mat seals the seams parallel to each other on the same weft, when the geosynthetics are stretched in the transverse direction, the supporting force is weak and the strength is weak.

However, the sewing machine according to the present invention can maintain a strong supporting force when the geosynthetics are stretched in the transverse direction by sewing the sewing lines such that the sewing lines are not located on the same weft by the diagonal lines or various combinations. FIG. 6 shows various suture line structures of the geosynthetic mat according to the present invention. (A) is a zigzag type sewing line structure composed of six lines, (B) is a zigzag type structure in which two left and right lines are zigzag type in a six line sealing line, (C) (E) is a zigzag structure in four lines, and (F) is a structure in which two left and right lines are zigzag in a four-line seaming line. This structure can be implemented by changing the positions of the hook 11, the pin 22 and the needle 31 in the hook bundle 10, the pin bundle 20 and the needle bundle 30 of the present invention. And modifications of such a structure can be easily carried out by those skilled in the art to which the present invention belongs.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: bundle of hooks 11: hook
12: hole 20: pin bundle
21: pin 22: pin
23: bolt 30: needle bundle
31: needle 32: hole
33: thread guide hole 34: thread guide groove
35:

Claims (5)

A sewing machine for sewing a geosynthetic fiber including a bundle of hooks (10), a bundle of pins (20) and a bundle of needles (30), and a sewing device for sewing two layers of geosynthetics by a knitting method,
The claw bundle 10 is formed with two rows of holes 12a and 12b each having six holes and the claws 11 are inserted and fixed in the holes of the predetermined zigzag position,
The pin bundle 20 has six pins 22 whose lengths are adjustable. The pins 22 are each capable of adjusting the protruding length by means of bolts 23,
Wherein the needle bundle (30) is formed with two rows of holes (32a, 32b) each having six holes, and the needle (31) is inserted and fixed in a hole in a predetermined zigzag position.
The method according to claim 1, characterized in that the hooks (11) are inserted and fixed in the holes of the two rows (12a, 12b) formed in the hooks (10) The protruding length of the pin 22 of the pin bundle 20 is determined and the position of the needle 31 of the needle bundle 30 is selected from the holes of the two rows 32a and 32b, Characterized in that a high strength geosynthetic mat having a predetermined seam line structure is manufactured.
The needle bar according to claim 1, wherein a thread guide hole (34a) corresponding to six holes (32a) of the needle bundle (30) is formed at an edge, and a thread guide groove (34b) corresponding to the six holes Wherein the ground wire is formed at an edge.
A geosynthetic fiber mat as claimed in any one of claims 1 to 3, which is sewn with a sewing machine for sewing a geosynthetic fiber so that the sewing lines are not located on the same weft by diagonal lines or by various combinations.
The geosynthetic fiber mat according to claim 4, wherein the seaming line is four-line, five-line, or six-line.

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