KR102192264B1 - Manufacturing system for breathable fabric - Google Patents

Abstract

The present invention relates to a breathable fabric manufacturing system implemented to manufacture a breathable fabric, capable of applying magnetic force and easily stretching pleats by using spandex, magnetic yarn, shape memory yarn and the like. The present invention includes a weaving unit for manufacturing a primary fabric by weaving prepared weaving yarn.

Description

Breathable fabric manufacturing system {MANUFACTURING SYSTEM FOR BREATHABLE FABRIC}

The present invention relates to a breathable fabric manufacturing system, and more particularly, using spandex, magnetic yarn and shape memory yarn, etc., to manufacture a breathable fabric capable of easily spreading the action of magnetic force and wrinkles. It's about the system.

In order to provide clothing such as sportswear as a fabric using sweat-absorbing, quick-drying functional yarn, there is a disadvantage that it is essential to perform single water-repellent processing from the woven fabric.In addition, the fabric of the clothing is in close contact with the human body to directly absorb sweat from the human body and quickly go outside. Since it is all configured to discharge sweat by the effect of dissipating it, it has disadvantages such as not being able to expect a large breathability from the fabric.

In order to solve the shortcomings of sportswear manufactured with sweat-absorbing quick-drying functional yarns such as Aerocool, Coolmax, etc., recently, ventilation holes are formed in the fabric to allow air to enter and exit the body while reducing body temperature. Fabrics having a have been developed. Prior literature related to this includes Korean Patent Publication No. 10-0463229.

However, the conventional breathable fabric has a problem in that when the fabric is folded or rolled and stored, the fabric material is flexible and distracted or wrinkles are easily generated by the use of the fabric.

On the other hand, the above-described background technology is technical information that the inventor possessed for derivation of the present invention or acquired during the derivation process of the present invention, and is not necessarily a known technology disclosed to the general public prior to filing the present invention. .

Korean Patent Registration No. 10-0463229 Korean Patent Registration No. 10-0450626

One aspect of the present invention provides a breathable fabric manufacturing system implemented to manufacture a breathable fabric capable of easily spreading out wrinkles and the action of magnetic force by using spandex, magnetic yarn, and shape memory yarn.

In addition, it provides a breathable fabric manufacturing system implemented to manufacture a breathable fabric with easy wrinkle control.

In addition, the vibration or shock generated by the drive of each component in the weaving process is supported by using components that act as a buffer, so that the durability of the device is reduced according to the drive, thus preventing damage as much as possible. Provides a breathable fabric manufacturing system.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

A breathable fabric manufacturing system according to an embodiment of the present invention includes; a weaving unit for manufacturing a primary fabric by weaving the prepared weaving.

In one embodiment, a direct irradiation preparation unit for preparing a direct irradiation including spandex, magnetic yarn, shape memory yarn and melting yarn; And a melting yarn reduction unit for manufacturing a breathable fabric by reducing and processing the melting yarn during direct irradiation included in the first fabric manufactured by the weaving unit.

In one embodiment, the weaving unit, while rotating in a predetermined direction, a winding member for supplying a direct irradiation of one of spandex, magnetic yarn, shape memory yarn and melting yarn; A feeder having a header having a rotation axis parallel to the rotation axis of the winding member and perpendicular to the direction of direct irradiation, and receiving the direct irradiation from the winding member and simultaneously withdrawing the direct irradiation; An installation frame forming an inner space for connecting and installing the winding member, and in which the feeder is installed above the front end; A frame support installed under the installation frame to support the installation frame; An air hydraulic unit for aligning the direct irradiation by applying compressed air to the direct irradiation drawn from the feeder; A loom that receives spandex, magnetic yarn, shape memory yarn, and melted yarn individually to weave primary fabrics; And a plurality of loom supports installed at each lower corner of the loom to attenuate vibrations or shocks generated by driving of the loom.

In one embodiment, the frame support, a first support for supporting the lower side of the installation frame; A second pedestal facing the first pedestal and spaced apart from the rear end of the first pedestal to support a lower side of the installation frame; A first auxiliary pedestal that is spaced apart from the rear end of the second pedestal and is elevated as the first pedestal descends to support a lower rear end of the installation frame; A second auxiliary support that is spaced apart from the front end of the first support and is raised and lowered as the second support descends to support a lower front end of the installation frame; It is formed in a round "U" shape to the lower side, and is connected and installed so that the first pedestal is rotatable on the upper side of the front end, and the first auxiliary pedestal is rotatably connected to the upper side of the rear end, and as the first pedestal descends A first “U”-type link that rotates to lift the first auxiliary pedestal; Corresponding to the shape of the first “U”-type link, it is formed in a “U” shape rounded to the lower side, and the second pedestal is installed to be rotatable at the upper end of the rear end, and the second auxiliary pedestal is rotatable on the upper side of the front end. A second “U”-type link installed so as to be connected and rotated as the second pedestal descends to lift the second auxiliary pedestal; A first support box on which a lower side of the first “U” link is seated so as to support the first “U” link; The lower side of the second “U”-type link is seated so as to support the second “U”-type link, and the first “U”-type link is spaced apart from each other in the front and rear direction. And a second support box spaced apart from the first support box in a shear direction so as to be connected and installed by the second “U”-type link. And a base frame formed in a flat plate shape so that the first support box and the second support box can be installed on the upper side.

In one embodiment, the first support box, a support plate extending in the longitudinal direction of the front and rear; A first spring installed above the front end of the support plate; A second spring installed above the rear end of the support plate; A first support part having a lower end of the rear end connected to the upper side of the support plate so as to be rotatable, and having a lower end of the front end supported by the first spring; A second support part in which the front lower side is connected to the upper side of the support plate so as to be rotatable with the rear end lower side of the first support part, and the rear end lower side is supported by the second spring so that the front side is in close contact with the rear side of the first support part ; A first seating tunnel extending from an upper front side to a lower rear side of the first support part in response to the curvature of the first “U” link so that the first “U” link can be seated; And the second support part from the front lower side to the rear upper side in response to the curvature of the first “U” link so that the first “U” link can be seated by extending and facing the rear end of the first seating tunnel. It may include; a second seating tunnel extending to the formed.

In one embodiment, the first “U”-type link is rotated at the bottom so that the front end and the rear end can open in a direction away from each other as the upper ends of the first support and the second support rotate in a direction away from each other. The coaxial is formed, an upper rack gear may be formed along an upper side, and a lower rack gear may be formed along a lower side.

In one embodiment, the first seating tunnel may include a plurality of upper support portions formed along an upper surface to support an upper side of the first “U”-shaped link seated in the inner space; And a plurality of lower support portions formed along the lower side to support the lower side of the first “U”-shaped link seated in the inner space.

In one embodiment, the upper support portion, a sliding groove extending in an upper longitudinal direction from an upper surface of the inner space of the first seating tunnel; A support spring installed on the upper side of the sliding groove; A slider seated in the sliding groove, supported by the support spring, and sliding in the vertical direction along the sliding groove; And the upper side of the first “U” type link while being engaged with the upper rack gear so as to be rotatably connected to the lower side of the slider, and rotating as the first “U” type link moves along the first seating tunnel. It may include; a support gear for supporting the.

In one embodiment, the loom support, the lower plate is formed in the shape of a square plate to be installed on the bottom surface; An upper plate formed in a square plate shape corresponding to the shape of the lower plate to support the lower side of the loom; An intermediate support portion installed at an upper central portion of the lower plate to support a lower central portion of the upper plate; And four edge support portions installed at each upper edge portion of the lower plate to support each lower edge portion of the upper plate.

In one embodiment, the intermediate support portion, the upper cylinder is formed in the shape of a cylinder, a hemispherical upper mounting groove is formed on the lower side; A lower cylinder formed in a cylindrical shape corresponding to the shape of the upper cylinder, installed at a lower side of the upper cylinder, and having a hemispherical lower seating groove formed on the upper side; A support sphere formed in a spherical shape, wherein an upper portion is seated in the upper seating groove and a lower portion is seated in the lower seating groove to support between the upper cylinder and the lower cylinder; And a plurality of support elastic bodies that are provided along between the upper cylinder and the lower cylinder to support between the upper cylinder and the lower cylinder by using an elastic force.

In one embodiment, the lower cylinder may include a plurality of spherical support portions that are radially spaced apart from each other and installed along the lower seating groove so as to support the lower side of the support sphere seated in the lower seating groove. .

In one embodiment, the sphere support, a lower groove formed extending in the longitudinal direction so that the central axis toward the center of the support sphere; A lower spring installed under the lower groove; The lower groove is seated in the lower groove and supported by the lower spring, slides along the lower groove, and forms a seating ring along the upper rim to be seated on a seating jaw formed along the upper rim of the lower groove. A support bar supported so as not to descend from; And a seating sphere that is rotatably connected to the upper portion of the support bar so that the upper part is exposed to support the lower side of the support sphere.

In one embodiment, the support sphere, a support disk formed in the form of a disk installed in a horizontal direction passing through the center of the sphere so that the sphere can be divided into upper and lower; And an upper disk installed on the upper side of the upper cylinder and formed on each rim of the support disk facing the four corner support portions and extending in a vertical direction to support between the upper disk installed on the lower side of the lower cylinder. It may be provided with four disk supports;

In an embodiment, the loom support may further include an elevating link part for raising and lowering the edge support part as the disk support descends.

In one embodiment, the elevating link unit, a first bar is installed so as to be rotatably connected to the lower side of the disk support, the other side is installed so as to incline in a downward direction while looking at the corner support; A first elastic support installed under one side of the first bar to support one side of the first bar; One side is rotatably connected to the bottom surface of one side of the installation tunnel extending to the lower side of the corner support part along the inside of the lower plate, and the first elastic support is installed on one upper side, and the other side is the corner support part. A second bar installed so as to be inclined upwardly while looking and connected to the other side of the first bar so as to be rotatable; It is formed extending in a horizontal direction and is seated inside the installation tunnel, the first bar and the second bar are connected and installed so as to be rotatable together, and the first elastic support is lowered so that the first bar and the first bar are installed. A third bar that moves in the direction of the corner support as the gap between each side of the 2 bar decreases; A fourth bar connected to the other side of the installation tunnel so that the other side is rotatable, and one side is installed so as to be inclined in an upward direction so as to be rotatably connected to the other side of the third bar; A second elastic support installed on the other side of the fourth bar; A fifth bar whose other lower side is supported by the second elastic support, and one side is installed to be inclined downwardly to be connected to the other side of the third bar so as to be rotatable together with the fourth bar; And extending in a vertical direction so that a lower portion thereof is rotatably connected to the other side of the fifth bar, and the third bar moves in the direction of the corner support portion to each other side of the fourth bar and the fifth bar. It may include; a sixth bar that is lifted and lowered as the gap between them is widened to lift the edge support.

In one embodiment, the edge support portion, a lower support installed at one corner of the lower plate; A sliding through hole formed by passing through the lower support in an up-down direction so that the sixth bar is seated in a vertical direction and slides in an up-down direction; And an upper cap having an upper side formed in the form of a closed circular pipe, seated on the upper side of the lower support, supported by the sixth bar, and elevating as the sixth bar rises and falls.

According to one aspect of the present invention described above, it is possible to provide a fabric with elasticity secured by a functional yarn, and a ventilation line is formed in the warp and weft directions, and a ventilation hole is formed at the intersection, thereby improving breathability and durability. It is effective to increase the competitiveness of functional tailored fabrics by providing them.

In addition, after removing the woven melted yarn to form ventilation lines and ventilation holes on the fabric, functional yarns exist in the ventilation lines and ventilation holes formed in the place, enabling a new type of design to be produced. There is an effect that can greatly improve the quality of functional fabrics by supporting pores.

In addition, the vibration or shock generated by the driving of each of the components in the weaving process is supported by using components that have a buffering function, so that the durability of the device is deteriorated and damage caused by the driving can be prevented as much as possible.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within a range apparent to those of ordinary skill in the art from the contents to be described below.

1 is a view showing a schematic configuration of a breathable fabric manufacturing system according to an embodiment of the present invention.
2 is a view showing a schematic configuration of a breathable fabric manufacturing system according to another embodiment of the present invention.
3 is a view showing another embodiment of the weaving portion of FIG. 1.
4 is a view showing the frame support of FIG. 3.
5 is a view showing the first support box of FIG. 4.
6 is a diagram showing a connection relationship between a first support box and a second support box.
7 is a diagram showing a connection relationship between a second support and a first “U” type link.
8 is a diagram illustrating a connection relationship between a first “U”-shaped link and a first support and a second support.
9 is a view for explaining the rotation of the first support portion and the second support portion.
10 is a view showing an upper support and a lower support according to the present invention.
11 is a view showing the loom support of FIG. 2.
12 and 13 are views showing the intermediate support of FIG. 11.
14 is a view showing the concrete support of FIG. 13.
15 and 16 are views showing a support sphere according to another embodiment.
17 is a view showing another embodiment of the loom support of FIG. 3.
18 is a view showing another embodiment of the edge support.

DETAILED DESCRIPTION OF THE INVENTION The detailed description of the present invention to be described later refers to the accompanying drawings, which illustrate specific embodiments in which the present invention may be practiced. These embodiments are described in detail sufficient to enable a person skilled in the art to practice the present invention. It is to be understood that the various embodiments of the present invention are different from each other, but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description to be described below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scopes equivalent to those claimed by the claims. Like reference numerals in the drawings refer to the same or similar functions over several aspects.

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

1 is a view showing a schematic configuration of a breathable fabric manufacturing system according to an embodiment of the present invention.

1, the breathable fabric manufacturing system 1 according to an embodiment of the present invention includes a weaving portion 20 to be manufactured.

The weaving unit 20 manufactures a primary fabric by weaving the weaving prepared by the weaving preparation unit 10 prepared in the weaving preparation unit 10 to be described later in FIG. 2.

2 is a view showing a schematic configuration of a breathable fabric manufacturing system according to another embodiment of the present invention.

Referring to FIG. 2, a breathable fabric manufacturing system 2 according to another embodiment of the present invention includes a woven irradiation preparation unit 10, a weaving unit 20, and a melting yarn reduction unit 30.

Here, since the weaving part 20 is the same as the components of FIG. 1, its description will be omitted.

The weaving preparation unit 10 prepares for weaving including spandex (S1), magnetic yarn (S2), shape memory yarn (S3) and melting yarn (S4), and weaving the prepared weaving yarns (20) To pass.

The direct irradiation preparation unit 10 according to an embodiment of the present invention prepares direct irradiation for each type, including spandex (S1), magnetic yarn (S2), shape memory yarn (S3) and melting yarn (S4), Spandex (S1) is for manufacturing a breathable fabric with elasticity, and is preferably provided with fibers of a material having high elasticity.

In detail, the functional yarn S1 according to an embodiment may be spandex.

In addition, the magnetic yarn (S2) is a fiber having magnetic force including magnetic powder, and it is possible to obtain the magnetic yarn (S2) by containing the magnetic powder, and it is preferable to include it in the manufacturing process of the polymer fiber.

In this case, the magnetic powder is a fine powder, and the smaller the particle, the better the quality of the fiber. In detail, the magnetic powder is preferably contained in a size of 0.1 m or less, and it is preferable that the magnetic powder is contained and provided in an amount of 20% or more and 70% or less of the magnetic yarn 20.

When the magnetic yarn (S2) is included in the first fabric and weaved, there is an effect that the breathable fabric finally provided by the magnetic yarn (S2) is folded and is not disturbed when it is arranged, and can be maintained in a folded state by magnetic force.

In addition, an air layer may be provided between the folded fabrics so that one side and the other side of the breathable fabric can be kept in contact with each other to prevent volume increase. In addition, in the case of using the magnetic yarn (S2), it is possible to obtain an effect of blocking electromagnetic waves through the breathable fabric of the present invention by acting as well as having an effect of magnetic force and absorbing electromagnetic waves.

The shape memory yarn (S3) is preferably made of shape memory fibers that are restored to a predetermined shape designated in advance in the first temperature range. In detail, the first temperature range may be a temperature range of 40°C_ to 250°C_ at a higher temperature than room temperature, and more preferably 150°C_ to 250°C_ may be preferable.

The memory S3 may be formed of only a shape memory alloy having a very thin thickness, and may be provided in a shape in which the shape memory alloy and functional fibers are twisted.

In detail, it may be provided in a twisted shape such that two strands of functional fibers are one strand with each other in a single strand shape memory alloy. At this time, the functional fiber may be the same fiber as the above-described spandex (S1), but is preferably a fiber provided with a thickness thinner than that of the spandex (S1).

At this time, the thickness of the shape memory thread S3 may be preferably provided to be 0.1 mm or less in order to maintain the ventilation hole to be described later. In addition, the predetermined shape restored in the first temperature range is a shape that is bent or folded, and when heat in the first temperature range is applied to the fabric wrinkled by the shape memory thread (S3), the wrinkles can be easily spread out. I can do it.

The dissolving yarn (S4) dissolved and removed in the dissolving yarn reduction unit 30 to be described later is preferably prepared as a fiber, a water-soluble polymer fiber that is well soluble in water or diluted sodium hydroxide so as to form a ventilation hole and a ventilation line. Do.

In detail, there is no need to limit the type of the melting yarn (S4), and the melting yarn (S4) used in the warp direction and the weft direction may be the same type, but in some cases, the melting yarn (S4) is interposed in the weft direction. Partially dissolved yarn manufactured in a single strand through any one of a process, a covering process, a twisting process, and a braiding process may be used. Specifically, the dissolving yarn (S4) is 1 to 6 parts by weight of a bromine-containing flame retardant, and p-phenylene bis-o-tolylcarbodiimide, p, based on 100 parts by weight of polyester comprising one or more types of copolymerized polyester. -Phenylene-bipoly (4,4'-methyls-p-chlorophenylcarbodiimide, ethylene bis-diphenyl carbodiimide, biscyclohexylcarbodiimide), poly(4,4'-diphenylmethane Carbodiimide), poly(3,3' dimethyl-4,4'-diphenylmethanecarbodiimide), poly(naphthylenecarbodiimide), poly(p-phenylenecarbodiimide), poly(m-phenyl Ren carbodiimide), poly(tolylcarbodiimide), poly(diisopropylphenylenecarbodiimide), poly(methyl-diisopropylphenylenecarbodiimide), poly(triethylphenylenecarbodiimide) and poly( Triisopropyl phenylenecarbodiimide) may be prepared using 0.05 to 1.55 parts by weight of at least one compound selected from the group consisting of.

The melting yarn reduction unit 30 manufactures a breathable fabric by reducing the melting yarn (S4) during the direct irradiation included in the primary fabric manufactured by the weaving unit 20.

The breathable fabric manufacturing system 1 according to another embodiment of the present invention having the configuration as described above can provide a fabric with elasticity secured by a functional yarn, and a ventilation line is formed in the warp and weft directions while crossing By providing a functional fabric with improved breathability and durability by forming a ventilation hole in the part, it is possible to increase the competitiveness of the functional tailored fabric.

In addition, after removing the woven melted yarn to form ventilation lines and ventilation holes on the fabric, functional yarns exist in the ventilation lines and ventilation holes formed in the place, enabling a new type of design to be produced. By supporting the pores, the quality of functional fabrics can be greatly improved.

3 is a view showing another embodiment of the weaving portion of FIG. 1.

3, the weaving part 20a according to another embodiment is a winding member 21, a feeder 22, an installation frame 23, a frame support 100, an air hydraulic part 24, a loom ( 25) and a loom pedestal 200.

The winding member 21 supplies direct irradiation of one of spandex (S1), magnetic yarn (S2), shape memory yarn (S3), and melting yarn (S4) to the feeder 22 while rotating in a predetermined direction.

The feeder 22 is provided with a header having a rotation axis parallel to the rotation axis of the winding member 21 and perpendicular to the direction in which the direct irradiation proceeds, and receives the direct irradiation from the winding member 21 and at the same time receives the direct irradiation from the winding member 21. ) To withdraw.

The installation frame 23 forms an inner space for the winding member 21 to be connected and installed, and the feeder 22 is installed above the front end.

The frame support 100 is provided at each lower or lower corner of the installation frame 23 to support the installation frame 23.

The air hydraulic unit 24 applies compressed air to the direct irradiation drawn from the feeder 22 to align the direct irradiation.

The weaving machine 25 receives the spandex (S1), magnetic yarn (S2), shape memory yarn (S3), and melting yarn (S4) individually to weave the primary fabric.

In one embodiment, the loom 25 supplies a pair of spandex (S1) that is supplied two or more in a warp direction and one strand of magnetic yarn (S2) between the pair of spandex (S1), and a melting yarn ( S4) Repeat the process of supplying 1 strand, shape memory yarn (S3) 1 strand and melting yarn (S4) 1 strand, and at the same time repeating the same process as the weft direction weaving weaving weaving can do.

The loom support 200 is installed at each lower corner of the loom 25 to attenuate vibrations or impacts generated by driving of the loom 25.

The weaving unit 20a according to another embodiment having the configuration as described above is supported by using components that buffer vibrations or shocks generated by driving each of the components during the weaving process, Accordingly, the durability of the device is deteriorated and damage can be prevented as much as possible.

4 is a view showing the frame support of FIG. 3.

Referring to FIG. 4, the frame support 100 includes a first support 110, a second support 120, a first auxiliary support 130, a second auxiliary support 140, and a first “U” type link 150, a second “U” type link 160, a first support box 170, a second support box 180, and a base frame 190.

The first pedestal 110 is separated from the front end of the second pedestal 120 and supported by the first “U”-shaped link 150 (110a, see FIG. 8), and the lower or lower side of the installation frame 23 Each corner is supported.

The second pedestal 120 faces the first pedestal 110 and is spaced apart from the rear end of the first pedestal 110 and is supported by the second “U”-shaped link 160, and the lower side of the installation frame 23 Support.

The first auxiliary pedestal 130 is spaced apart from the rear end of the second pedestal 120 and supported (130a, see FIG. 8) by a first “U”-shaped link 150 and installed, and the first pedestal 110 It is raised and lowered by the first “U”-type link 150 that rotates as it descends to support the lower rear end of the installation frame 23.

The second auxiliary pedestal 140 is installed to be spaced apart from the front end of the first pedestal 110, and is elevated and installed by a second “U”-type link 160 that rotates as the second pedestal 120 descends. The lower front end of the frame 23 is supported.

The first “U”-type link 150 is formed in a “U” shape rounded to the lower side, and is connected to and installed so that the first pedestal 110 is rotatable on the upper front side, and the first auxiliary pedestal 130 on the rear upper side It is connected and installed so as to be rotatable, and rotates as the first pedestal 110 descends to raise and lower the first auxiliary pedestal 130.

In this case, the first auxiliary pedestal 130 should be installed at a lower position than the first pedestal 110.

The second “U” type link 160 is formed in a “U” shape rounded downward in response to the shape of the first “U” type link 150, and the second pedestal 120 is rotatable at the upper end of the rear end. It is connected and installed so that the second auxiliary pedestal 140 is rotatably connected to the upper side of the front end, and rotates as the second pedestal 120 descends to lift the second auxiliary pedestal 140.

In this case, the second auxiliary pedestal 140 should be installed at a lower position than the second auxiliary pedestal 140.

In the first support box 170, the lower side of the first “U” type link 150 is seated so as to support the first “U” type link 150.

In the second support box 180, the lower side of the second “U” type link 160 is seated so as to support the second “U” type link 160, and the first support 110 and the second support 120 is spaced from the first support box 170 in the shear direction so that it can be connected and installed by the first “U” type link 150 and the second “U” type link 160 in the front and rear direction. Installed.

The base frame 190 is formed in a flat plate shape so that the first support box 170 and the second support box 180 can be installed on the upper side.

Frame support 100 having the configuration as described above, by supporting each of the lower or lower corners of the installation frame 23, generated according to the driving of the weaving portion 20a according to another embodiment as described above. The accuracy and durability of operation can be improved by buffering vibration or shock.

5 is a view showing the first support box of FIG. 4.

5, the first support box 170, a support plate 171, a first spring 172, a second spring 173, a first support 174, a second support 175, the first It includes one settling tunnel 176 and a second settling tunnel 177.

Here, the second support box 180 is installed to be spaced apart from the first support box 170, as shown in FIG. 6, but is formed of the same configuration, and a description thereof will be omitted below in order to avoid duplication of description. .

The support plate 171 is formed to extend in the longitudinal direction of the front and rear and is installed on the floor surface of the facility in which the present invention is installed.

The first spring 172 is provided on the upper front end of the support plate 171 and supports the lower front end 174a of the first support 174.

The second spring 173 is installed on the upper rear end of the support plate 171 to support the lower rear end 175a of the second support 175.

The first support part 174 is connected and installed so that the rear end lower side is rotatable to the upper side of the support plate 171, and the front lower side 174a is supported by the first spring 172.

The second support 175 is connected and installed (A) so that the front lower side is rotatable with the rear end lower side of the first support 174 on the upper side of the support plate 171, and the rear lower side 175a is a second spring ( It is supported by 173 so that the front surface is in close contact with the rear surface of the first support part 174.

In one embodiment, the second support portion 175, as shown in Figure 7 so that the first "U" type link 150 to prevent movement in the direction of the first auxiliary pedestal 130 using an elastic force. Likewise, a first ring (B1) installed below the rear end of the first “U”-type link 150 and a jersey spring (S) having each end installed on the second ring (B2) installed on the rear side may be provided. .

The first seating tunnel 176 corresponds to the curvature of the first “U”-type link 150 so that the first “U”-type link 150 is seated and slidable, the front upper side of the first support part 174 It is formed extending from the rear to the lower side.

The second seating tunnel 177 faces the rear end of the first seating tunnel 176 and extends so that the first “U”-type link 150 is seated and slidably moves. ) Is formed extending from the lower front side to the upper rear side of the second support 175 corresponding to the curvature.

In one embodiment, the first "U"-type link 150, as shown in Figure 9, as each top of the first support 174 and the second support 175 rotate in a direction away from each other, the shear and As shown in FIG. 8, a rotation shaft 151 is formed in the lower part so that the rear ends can be opened in a direction away from each other, and an upper rack gear 152 is formed along the upper side, and a lower rack gear ( 153) may be formed.

In one embodiment, the first seating tunnel 176 may include a plurality of upper support portions 178 and a plurality of lower support portions 179.

The upper support part 178 is formed along the upper side to support the upper side of the first “U”-shaped link 150 seated in the inner space.

The lower support part 179 is formed along the lower side to support the lower side of the first “U” type link 150 seated in the inner space.

10 is a view showing an upper support and a lower support according to the present invention.

Referring to FIG. 10, the upper support part 178 includes a sliding groove 1781, a support spring 1782, a slider 1787, and a support gear 1784.

Here, the lower support part 179 is a vertically symmetrical structure with the components of the upper support part 178 as shown in FIG. 10, and each component may be equally applied. The description will be omitted to avoid overlapping descriptions. To

The sliding groove (1781) is formed extending in the longitudinal direction from the upper side of the inner space of the first seating tunnel (176), the support spring (1782) is installed on the upper side, and the slider (1783) slides in the vertical direction. do.

The support spring 1782 is installed on the upper side of the sliding groove 1781 to support the slider 1783 using an elastic force.

The slider 1783 is seated in the sliding groove 1781 and supported by a support spring 1782, and slides in the vertical direction along the sliding groove 1781, and a support gear 1784 is connected and installed on the lower side. do.

The support gear 1784 is connected to the upper rack gear 152 so as to be rotatably connected to the lower side of the slider 1783, and the first “U” type link 150 moves along the first seating tunnel 176 As it rotates, the upper side of the first “U”-type link 150 is supported.

11 is a view showing the loom support of FIG. 2.

Referring to FIG. 11, the loom support 200 includes a lower plate 210, an upper plate 220, an intermediate support 230, and four corner support 240.

The lower plate 210 is formed in the shape of a square plate and is installed on the bottom surface of the facility in which the present invention is installed, and the intermediate support 230 and the four corner support 240 are respectively installed on the upper side.

The upper plate 220 is formed in the shape of a square plate corresponding to the shape of the lower plate 210 and is supported and installed by the intermediate support 230 and the four corner support 240, and the loom 25 is seated on the upper side. Support the lower side.

The intermediate support 230 is installed at the upper central portion of the lower plate 210 to support the lower central portion of the upper plate 220.

The corner support part 240 is installed at each upper corner of the lower plate 210 to support each lower corner of the upper plate 220.

The loom support 200 having the configuration as described above is generated by the driving of the loom 25 by supporting the lower side of the loom 25 using the intermediate support 230 and the four corner support 240 Not only can the loom 25 be stably driven by buffering vibrations or shocks, etc., it is also possible to improve the durability of the device by performing a seismic function even when the equipment installed with the present invention is shaken due to an earthquake.

12 and 13 are views showing the intermediate support of FIG. 11.

12 and 13, the intermediate support 230 includes an upper cylinder 231, a lower cylinder 232, a support sphere 233, and a plurality of support elastic bodies 234.

The upper cylinder 231 is formed in a cylindrical shape, and a hemispherical upper seating groove (H1) is formed on the lower side to be seated on the upper side of the support sphere 233 to support the upper plate 220.

The lower cylinder 232 is formed in a cylindrical shape corresponding to the shape of the upper cylinder 231 and installed on the lower side of the upper cylinder 231, and a hemispherical lower seating groove (H2) is formed on the upper side to form a support sphere ( It supports the lower side of 233 and is installed on the upper side of the lower plate 210.

The support sphere 233 is formed in a spherical shape, the upper part is seated in the upper seating groove (H1) and the lower part is seated in the lower seating groove (H2) to support between the upper cylinder 231 and the lower cylinder (232).

A plurality of support elastic bodies 234 are installed along the upper cylinder 231 and the lower cylinder 232 to support between the upper cylinder 231 and the lower cylinder 232 using an elastic force.

In one embodiment, the support elastic body 234 is seated in the upper groove 2331 formed along the lower edge of the upper cylinder 231, the lower groove formed along the upper edge of the lower cylinder 232 ( 2321) may be installed by seating the lower part.

In one sealing example, the lower cylinder 232 is a plurality of radially spaced apart from each other along the lower seating groove (H2) to support the lower side of the support sphere 233 seated in the lower seating groove (H2). It may be provided with a spherical support 235.

And, the upper cylinder 231, a plurality of spherical support that is installed radially spaced apart from each other along the upper seating groove (H1) to support the upper side of the support sphere 233 seated in the upper seating groove (H1) ( 236) can be provided.

14 is a view showing the concrete support of FIG. 13.

Referring to FIG. 14, the spherical support 235 includes a lower groove 2351, a lower spring 2352, a support bar 2353, and a seating sphere 2354.

Here, the spherical support 236 of the upper cylinder 231 has the same configuration as the spherical support 235 of the lower cylinder 232, and a description thereof will be omitted below in order to avoid overlapping descriptions.

The lower groove 2351 is formed to extend in the longitudinal direction so that the central axis faces the center of the support sphere 233, and the lower spring 2352 is installed on the lower side, and the support bar 2353 is seated and slides in the vertical direction. Move.

The lower spring 2352 is installed under the lower groove 2351 and supports the support bar 2353 using an elastic force.

The support bar 2353 is seated in the lower groove 2351 and supported by the lower spring 2352, slides along the lower groove 2351, and forms a seating ring 2355 along the upper edge to form a lower groove. It is seated on the seating protrusion 2356 formed along the upper rim of the 2351 and supported so as not to descend from the lower groove 2351, and the seating sphere 2354 is rotatably connected to the upper side.

The seating sphere 2354 is rotatably connected to the upper portion of the support bar 2353 so that the upper part is exposed to support the lower side of the support sphere 233.

The spherical support 235 having the configuration as described above effectively attenuates vibrations or impacts generated between the lower plate 210 and the upper plate 220 by radially supporting several lower portions of the support sphere 233. It can prevent equipment from being damaged.

15 and 16 are views showing a support sphere according to another embodiment.

15 and 16, a support sphere 233 according to another embodiment includes a support disk 2331 and four disk supporters 2332.

The support disk 2331 is formed in a disk shape that passes through the center of the sphere and is installed in a horizontal direction so that the sphere can be divided into upper and lower portions, and is seated in the space between the lower plate 210 and the upper plate 220.

The disk support 2332 is installed on each rim of the support disk 2331 facing the four corner support portions 240, and is formed to extend in the vertical direction and is installed on the upper side of the upper cylinder 231. ) And the lower disk 2322 installed at the lower side of the lower cylinder 232 may be supported.

In one embodiment, the disk support 2332 is more elastically supported between the upper disk 2312 and the lower disk 2322

An upper spring F1 may be installed between the upper disc 2312 and a lower spring F2 may be installed between the lower disc 2322.

17 is a view showing another embodiment of the loom support of FIG. 3.

Referring to FIG. 17, a loom support 200 according to another embodiment includes a lower plate 210, an upper plate 220, an intermediate support part 230, four corner support parts 240, and an elevating link part 250. do.

Here, the lower plate 210, the upper plate 220, the intermediate support portion 230, and the four edge support portions 240 are the same as the components of FIG. 11, and thus description thereof will be omitted.

The elevating link part 250 raises and lowers the edge support part 240 which is installed to face the corresponding disk support 2332 as one disk support 2332 descends.

In one embodiment, the elevating link unit 250, the first bar 251, the first elastic support 252, the second bar 253, the third bar 254, the fourth bar 255, the It includes 2 elastic support (256), a fifth bar (257) and a sixth bar (258).

The first bar 251 is connected to the lower side of the disk support 2332 so that one side is rotatable, and the other side is installed to be inclined downward while looking at the corner support part 240.

The first elastic support 252 is installed under one side of the first bar 251 to support one side of the first bar 251.

The second bar 253 is connected to the bottom surface of one side of the installation tunnel T extending to the lower side of the edge support part 240 along the inside of the lower plate 210 so that one side is rotatable, and 1 The elastic support 252 is installed, and the other side is installed so as to be inclined upward while looking at the corner support part 240 to be connected to the other side of the first bar 251 so as to be rotatable.

The third bar 254 is extended in a horizontal direction and seated in the installation tunnel T, and the first bar 251 and the second bar 253 are connected and installed so as to be rotatable together on one side. 1 As the elastic support 252 descends and the gap between each side of the first bar 251 and the second bar 253 decreases, it moves in the direction of the edge support part 240.

The fourth bar 255 is connected to the bottom surface of the other side of the installation tunnel T so that the other side is rotatable, and the fourth bar 255 is installed so that one side is inclined upward so that it can be rotated to the other side of the third bar 254 It is installed so as to be connected.

The second elastic support 256 is installed on the upper side of the other side of the fourth bar 255.

The fifth bar 257 is supported by the second elastic support 256 on the other lower side, and is installed so that one side is inclined in the downward direction, so that the fourth bar 255 and the fourth bar 255 are disposed on the other side of the third bar 254. It is connected and installed so that it can be rotated together.

The sixth bar 258 is extended in a vertical direction and the lower portion is connected to be rotatable to the other side of the fifth bar 257, and the third bar 254 moves in the direction of the edge support part 240 As the gap between each other side of the fourth bar 255 and the fifth bar 257 increases, it is lifted and lowered to lift the edge support part 240.

18 is a view showing another embodiment of the edge support.

Referring to FIG. 18, the edge support part 240 includes a lower support 241, a sliding through hole 242, and an upper cap 243.

The lower support 241 is installed at one corner of the lower plate 210, and the upper cap 243 is seated on the upper side.

The sliding through hole 242 is formed by passing through the lower support 241 in the vertical direction so that the sixth bar 258 is seated in a vertical direction and slid in the vertical direction.

The upper cap 243 is formed in the form of a circular pipe whose upper side is sealed and is seated on the upper side of the lower support 241 and supported by the sixth bar 258, and is raised and lowered as the sixth bar 258 is raised and lowered. It lifts the upper plate 220.

The above-described embodiments are for illustrative purposes only, and those of ordinary skill in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. You can understand. Therefore, it should be understood that the above-described embodiments are illustrative and non-limiting in all respects. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope to be protected through the present specification is indicated by the claims to be described later rather than the detailed description, and should be interpreted as including all changes or modified forms derived from the meaning and scope of the claims and the concept of equivalents thereof. .

1, 2: breathable fabric manufacturing system
10: Direct investigation preparation department
20: weave
30: melting sand reduction part

Claims (2)

Weaving unit for manufacturing a primary fabric by weaving the prepared weaving; And
A direct irradiation preparation unit for preparing direct irradiation including spandex, magnetic yarn, shape memory yarn, and melting yarn; And a melting yarn reducing unit for manufacturing a breathable fabric by reducing and processing the melting yarn during direct irradiation included in the first fabric manufactured by the weaving unit,
The weaving unit, while rotating in a predetermined direction, a winding member for supplying a direct irradiation of one of spandex, magnetic yarn, shape memory yarn, and melting yarn; A feeder having a header having a rotation axis parallel to the rotation axis of the winding member and perpendicular to the direction of direct irradiation, and receiving the direct irradiation from the winding member and simultaneously withdrawing the direct irradiation; An installation frame forming an inner space for connecting and installing the winding member, and in which the feeder is installed above the front end; A frame support installed under the installation frame to support the installation frame; An air hydraulic unit for aligning the direct irradiation by applying compressed air to the direct irradiation drawn from the feeder; A loom that receives spandex, magnetic yarn, shape memory yarn, and melted yarn individually to weave primary fabrics; And a plurality of loom supports installed at each lower corner of the loom to attenuate vibrations or shocks generated by the driving of the loom.
The frame support includes: a first support supporting a lower side of the installation frame; A second pedestal facing the first pedestal and spaced apart from the rear end of the first pedestal to support a lower side of the installation frame; A first auxiliary pedestal that is spaced apart from the rear end of the second pedestal and is elevated as the first pedestal descends to support a lower rear end of the installation frame; A second auxiliary support that is spaced apart from the front end of the first support and is raised and lowered as the second support descends to support a lower front end of the installation frame; It is formed in a round "U" shape to the lower side, and is connected and installed so that the first pedestal is rotatable on the upper side of the front end, and the first auxiliary pedestal is rotatably connected to the upper side of the rear end, and as the first pedestal descends A first “U”-type link that rotates to lift the first auxiliary pedestal; Corresponding to the shape of the first “U”-type link, it is formed in a “U” shape rounded to the lower side, and the second pedestal is installed to be rotatable at the upper end of the rear end, and the second auxiliary pedestal is rotatable on the upper front side. A second “U”-type link installed so as to be connected and rotated as the second pedestal descends to lift the second auxiliary pedestal; A first support box on which a lower side of the first “U” link is seated so as to support the first “U” link; The lower side of the second “U”-type link is seated so as to support the second “U”-type link, and the first “U”-type link is spaced apart from each other in the front and rear direction. And a second support box spaced apart from the first support box in a shear direction so as to be connected and installed by the second “U”-type link. And a base frame formed in a flat plate shape so that the first support box and the second support box can be installed on the upper side,
The first support box may include a support plate extending in a longitudinal direction of the front and rear; A first spring installed above the front end of the support plate; A second spring installed above the rear end of the support plate; A first support part having a lower end of the rear end connected to the upper side of the support plate so as to be rotatable, and having a lower end of the front end supported by the first spring; A second support part in which the front lower side is connected to the upper side of the support plate so as to be rotatable with the rear end lower side of the first support part, and the rear end lower side is supported by the second spring so that the front side is in close contact with the rear side of the first support part ; A first seating tunnel extending from an upper front side to a lower rear side of the first support part in response to the curvature of the first “U” link so that the first “U” link can be seated; And the second support part from the front lower side to the rear upper side in response to the curvature of the first “U” link so that the first “U” link can be seated by extending and facing the rear end of the first seating tunnel. Includes; a second seating tunnel formed extending into,
The loom base is formed in the shape of a square plate and is installed on the bottom surface; An upper plate formed in a square plate shape corresponding to the shape of the lower plate to support the lower side of the loom; An intermediate support portion installed at an upper central portion of the lower plate to support a lower central portion of the upper plate; And four edge support portions installed at respective upper corner portions of the lower plate to support respective lower corner portions of the upper plate; and
The intermediate support portion, the upper cylinder is formed in the shape of a cylinder, a hemispherical upper seating groove is formed on the lower side; A lower cylinder formed in a cylindrical shape corresponding to the shape of the upper cylinder, installed at a lower side of the upper cylinder, and having a hemispherical lower seating groove formed on the upper side; A support sphere formed in a spherical shape, wherein an upper portion is seated in the upper seating groove and a lower portion is seated in the lower seating groove to support between the upper cylinder and the lower cylinder; And a plurality of support elastic bodies installed along between the upper cylinder and the lower cylinder to support between the upper cylinder and the lower cylinder using an elastic force. delete

Images