KR102039858B1 - Loom system for manufacturing fabric and fabric thereof - Google Patents

Abstract

The present invention relates to a textile system capable of reinforcing physical properties of a carbon preform and a textile manufactured by using the system. The textile system comprises: a frame body (600) through which a woven textile passes; a warp supply unit (610); a weft supply unit (620); a warp opening formation unit (630); a horizontal striking unit (640); a textile winding unit (650); and a shuttle (330).

Description

Fabric weaving system and fabrics manufactured using the system {LOOM SYSTEM FOR MANUFACTURING FABRIC AND FABRIC THEREOF}

The present invention relates to a weaving system and a fabric manufactured using the system, and more particularly, to increase the productivity of the carbon preform by automating the production of unidirectional carbon fiber fabric forming the carbon preform through a weaving method, It is possible to maintain a constant surface density of the unidirectional carbon fiber fabric forming the carbon preform and to uniformly arrange the continuous carbon fibers in the carbon preform, thereby reinforcing the physical properties of the carbon preform and the fabric produced using the system. It is about.

In general, in the manufacturing process of unidirectional carbon fiber fabric forming carbon preform, 1. Tow-shaped polyacrylonitrile (PAN) -based carbon fiber (Oxi-PAN Fiber, Carbon Fiber) bundle is spread out flat and needle punching equipment, etc. Method for producing a unidirectional carbon fiber fabric using the method, and 2. Method of using a carbon fiber web (Web), needle to the carbon fiber web on the polyacrylonitrile (PAN) -based carbon fiber bundles of flat toe-shaped It uses a method for producing unidirectional carbon fiber fabrics using punching equipment and the like.

In addition, the conventional methods for manufacturing the unidirectional carbon fiber fabrics can only be performed manually by the nature of the manufacturing method, according to the method of manufacturing the unidirectional carbon fiber fabrics by this manual method, the area control and productivity of the unidirectional carbon fiber fabrics Limits arise, which impedes the production of large quantities of carbon preforms.

In addition, according to the conventional method of manufacturing a unidirectional carbon fiber fabric by manual, the unidirectional, surface density uniformity of the unidirectional carbon fiber fabric, uniform orientation of the continuous carbon fiber is lowered, which reduces the physical properties of the carbon preform Acts as

In addition, the nonuniform one-way carbon fiber fabric causes the needle to break when the carbon preform is manufactured using the needle punching method, and the carbon preform containing the broken needle cannot be used as a product.

In addition, conventionally, since one weft supply part and one guide needle are provided, there is a problem in that the whole work is stopped when the weft thread is broken.

The present invention has been made in view of the above-mentioned conventional problems, unidirectional carbon fiber fabric to form a carbon preform through a weaving method using polyacrylonitrile (PAN) -based carbon fiber (Oxi-PAN Fiber, Carbon Fiber) Improves the physical properties of carbon preforms by unidirectional, surface density uniform distribution, and uniform orientation of carbon fibers, and especially produces large quantities of carbon preforms by increasing the productivity of unidirectional carbon fiber fabrics through automation of the weaving process. Its purpose is to be able to easily control the area of the unidirectional carbon fiber fabric using mechanical properties.

In addition, the weft supply unit is provided by stacking a plurality of upper, lower, left and right, and provided with a plurality of guide needles for supplying the weft to the shuttle, the weft feeder in operation by the guide needle to select the weft to supply to the shuttle Its purpose is to allow the weaving operation to be resumed immediately by using another weft feeder if it breaks down or the material of the weft feeder runs out.

In order to achieve the above object of the invention, the present invention,

A frame body 600 through which the woven fabric is passed; An inclined supply unit 610 installed on an upper portion of the rear of the frame body and winding inclined and gradually releasing the inclined to supply the inclined; A weft supply unit 620 which is installed on one side of the frame body and gradually loosens the weft yarn for weaving and supplies the weft yarn; The inclined opening which divides the inclined from the inclined supply unit into two groups and moves the inclined of each group up and down so as to form an opening through which the weft yarns are introduced after each group is repeatedly opened in the opposite direction. Forming unit 630; A horizontal striking part 640 for advancing after weaving the weft yarn and striking the weft yarn which is entwined; A fabric winding unit 650 for winding the woven fabric while passing through the frame body; It comprises a shuttle 330 to transfer the weft supplied from the weft supply in a horizontal direction to induce the weaving operation is combined with the warp yarn is inclined; The weft supply unit 620 is provided by stacking a plurality of up, down, left, and right, and provided with a plurality of guide needles 660 for supplying the weft to the shuttle, the guide needle is selected to supply the weft to the shuttle 330. It is characterized by being made.

In addition, dust measuring means (1000a) is installed on one side of the frame body to measure the dust generated around the frame body; It is characterized in that it comprises an odor spreading device 1100 electrically connected to the dust measuring means and outputs odor to the outside according to the control signal of the dust measuring means.

The dust measuring means may include a housing for collecting dust, a wire mesh 10a installed inside the housing 4 to remove moisture from the input dust and directing only the correct dust to pass through the wire mesh. Wire mesh rotary motor 10b for inserting and rotating the wire mesh to accelerate the removal of water present in the air, and a heater for supplying heat to the wire mesh to rapidly evaporate the moisture contacting the wire mesh. Electric means for providing heat (10c), infrared ray transmitting means (A) for emitting infrared rays in order to detect the moisture-removed dust, and light positioned to face the infrared ray transmitting means and emitted from the infrared ray transmitting means And the output voltage of the infrared receiving means (B) and the infrared receiving means (B) for determining the dust inflow according to the degree of the received amount. Is smaller than the value is made, including the dust measurement controller (C) for controlling so that the input voltage is increased in the infrared transmitting section (A); One side of the housing further installed a humidity sensor (7) by the dust measurement control unit (C) according to the humidity to control the rotation speed of the wire mesh rotary motor (10b) if the humidity is high based on the rotation speed of the wire mesh rotary motor (10b) At the same time, when the heater heat is higher than the reference and the humidity is low, the rotation speed of the wire mesh rotating motor 10b is lower than the reference and the heater heat is lower than the reference.

In addition, the wire mesh (10a) is coupled to the vertical guide rod (10a-2) coupled to the horizontal guide rod (10a-1) and the vertical groove (5) of the housing to be detachable to the shaft of the wire mesh rotary motor (10b) If necessary, the horizontal guide rod 10a-1 is separated from the wire mesh rotation motor 10b and at the same time the vertical guide rod 10a-2 is separated from the housing 4 to remove contaminants present in the wire mesh. to be.

In addition, the malodor application device 1100, the housing 1110; A battery 1120 installed inside the housing 1110 and receiving electricity from the outside to charge electricity and provide electricity to the device; A rotation motor 1130 electrically connected to the battery and receiving power from the battery and converting the same into mechanical rotational motion; A motor shaft 1131 which is installed on the central axis of the rotary motor and rotates in correspondence with the rotation of the rotary motor, the bottom surface of which is in the form of a waveform; A vertical drive cylinder 1140 positioned at a lower end of the rotary motor and flowing while moving up and down by converting rotation of the rotary motor into a reciprocating vertical motion; Located in the upper portion of the vertical drive cylinder 1140, but is located on the central axis, while being in mechanical contact with the motor shaft 1131 of the rotary motor 1130, coupled with the motor shaft 1131 of the rotary motor 1130 And a rotation shaft 1141 which moves up and down while repeating separation. It is installed on the outer periphery of the up and down drive cylinder 1140, one side is fixed to the locking jaw of the inner housing and the other side is fixed to the locking jaw of the up and down drive cylinder to support the up and down drive cylinders to maintain the up and down drive cylinder to move up and down Elevating support springs (1150) to be able to support; Inserted and coupled to the inside of the up and down drive cylinder 1140, the cylinder shape as a whole, and a plurality of drug passing holes (1161) is provided on the bottom, it is made to supply the drug while flowing up and down according to the movement of the up and down drive cylinder Malodor drug applicator 1160; One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the odor drug applicator 1160 by temporarily fixing the upper and lower drive cylinders and odor drug applicator 1160 at the same time based on the housing ) Is characterized in that it comprises a odor drug applicator temporary fixing means 1180 to prevent the fall down by gravity action.

In addition, the odor drug applicator temporary fixing means 1180, the end is made of a sharp wedge shape is forced through the coupling holes of the up and down driving cylinder and the coupling hole of the drug applicator, so that the odor drug applicator of the vertical drive cylinder A catching hook 1181 for maintaining a state coupled to the inner circumference; A connecting piece 1182 which is integrally connected to the hooking hook 1181 in a diagonal direction and guides the hooking hook 1181 to move in a clockwise or counterclockwise direction by a rotational movement; A rotation support hinge 1183 installed between the connection piece 1182 and the hook hook 1181 to support the connection piece being rotated; It is installed between the connecting piece 1182 and the up and down drive cylinder 1140 and pushes the connecting piece outwards so that the hook hook 1181 flows in a counterclockwise direction to maintain the drug applicator coupled to the up and down drive cylinder. When the connection piece is pressed by the external force and compressed in the vertical drive cylinder direction, the hook 1118 is separated from the vertical drive cylinder 1140 and the drug applicator 1160 while the drug applicator 1160 is vertically driven cylinder. A support spring 1184 for inducing removal from the nozzle 1140; A sliding flow piece (1185) installed at the end of the connecting piece (1182) and simultaneously moving when the hook (1181) and the connecting piece (1182) move up and down in accordance with the vertical flow of the vertical drive cylinder (1140); Slidingly coupled with the sliding flow piece 1185 to support the vertical movement of the sliding flow piece 1185, push the odor drug applicator 1160 toward the vertical drive cylinder 1140 at the time of replacement, the connection piece 1118 By pressing, the connecting piece 1182 rotates about the hinge pin 1183 for rotational support so that the hook 1118 is separated from the upper and lower driving cylinders 1140 and the drug applicator 1160 while the odor drug applicator 1160 is applied. ) Is characterized in that it comprises a push button (1186) to guide the removal from the vertical drive cylinder (1140).

As described above, the present invention, through the weaving method using polyacrylonitrile (PAN) -based carbon fibers (Oxi-PAN Fiber, Carbon Fiber), unidirectional, surface density uniform distribution of the unidirectional carbon fiber fabric to form a carbon preform To improve the physical properties of carbon preforms with uniform orientation of carbon fibers, and to produce large quantities of carbon preforms by increasing the productivity of unidirectional carbon fiber fabrics through automated weaving process, and to produce unidirectional carbon fibers using mechanical properties of weaving process. There is an effect that can easily adjust the area of the fabric.

In addition, the weft supply unit is provided by stacking a plurality of upper, lower, left and right, and provided with a plurality of guide needles for supplying the weft to the shuttle, the weft feeder in operation by the guide needle to select the weft to supply to the shuttle If it is broken or the weft feeder runs out of material, weaving can be resumed immediately using another weft feeder.

1 is a schematic configuration diagram of a unidirectional carbon fiber fabric weaving system according to a preferred embodiment of the present invention.
2 is a side cutaway view of the weaving system of FIG.
3 is a partially enlarged view for explaining the operation of the shuttle applied to the weaving system of FIG.
4 is a partially enlarged view showing a woven mesh structure made of continuous carbon fibers and warp yarns formed by the weaving system of FIG.
5 is a configuration diagram of an embodiment of the present invention.
Figure 6 is a view showing both the weft supply and the oblique supply of the present invention.
7 is a view mainly showing the weft supply of the present invention.
8 is a specific view of the weft supply unit of the present invention.
9 is a specific view of the guide needle of the present invention.
10 is a conceptual diagram of the dust measurement and alarm output of the present invention.
11 is a conceptual diagram of dust measurement of the present invention.
12 is a perspective view of a dust measuring device of the present invention.
Figure 13 is an exploded perspective view of the dust measuring apparatus of the present invention.
14 is a plan view of the dust measurement apparatus of the present invention.
15 is a conceptual view of the operation of the dust measuring apparatus of the present invention.
16 is a detailed view of a concave lens light collecting original of the present invention.
17 is an embodiment of a concave lens of the present invention.
18 is an exploded perspective view of the malodor chemical liquid applying device of the present invention.
19 is a cross-sectional view and a main portion cross-sectional view of the odor chemical liquid applying device of the present invention.
20 is an enlarged cross-sectional view of a main portion of the malodorous chemical liquid applying device of the present invention.
21 is a configuration of the rotary motor and the vertical drive cylinder of the odor chemical liquid applying apparatus of the present invention.
Figure 22 is an enlarged view of the main portion of the rotary motor and the vertical drive cylinder of the malodor chemical liquid applying apparatus of the present invention.
Figure 23 is a block diagram of the temporary fixing means of the malodor chemical solution coating apparatus of the present invention.
24 is another angle configuration diagram of the temporary fixing means of the malodor chemical solution coating device of the present invention.
Figure 25 is a block diagram of the chemical liquid passage hole of the present invention.

Hereinafter, with reference to the accompanying drawings and description will be described in detail the operating principle of the preferred embodiment of the present invention. However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

In addition, preferred embodiments of the present invention to be carried out below are already provided in each system functional configuration to efficiently describe the technical components constituting the present invention, or system functions commonly provided in the technical field to which the present invention belongs. The configuration will be omitted, and described mainly on the functional configuration to be additionally provided for the present invention.

If those skilled in the art to which the present invention pertains, it will be able to easily understand the function of the components already used in the prior art among the omitted functional configuration not shown below, and also the configuration omitted as described above The relationship between the elements and the components added for the present invention will also be clearly understood.

In addition, the following examples will be used to appropriately modify the terms so that those skilled in the art to clearly understand the technical features of the present invention to effectively understand, but the present invention It is by no means limited.

As a result, the technical spirit of the present invention is determined by the claims, and the following embodiments are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It's just

In addition, it is to be understood that all detailed descriptions, including the principles, aspects, and embodiments of the present invention, as well as listing specific embodiments, are intended to include structural and functional equivalents of these matters. In addition, these equivalents should be understood to include not only equivalents now known, but also equivalents to be developed in the future, that is, all devices invented to perform the same function regardless of structure.

Thus, for example, it should be understood that the block diagrams herein represent a conceptual view of example circuitry embodying the principles of the invention. Similarly, all flowcharts, state transitions, pseudocodes, and the like are understood to represent various processes performed by a computer or processor, whether or not the computer or processor is substantially illustrated on a computer readable medium and whether the computer or processor is clearly shown. Should be.

The functionality of the various elements shown in the figures, including functional blocks represented by a processor or similar concept, can be provided by the use of dedicated hardware as well as hardware capable of executing software in association with appropriate software. When provided by a processor, the functionality may be provided by a single dedicated processor, by a single shared processor or by a plurality of individual processors, some of which may be shared.

In addition, the explicit use of terms presented in terms of processor, control, or similar concept should not be interpreted exclusively as a citation to hardware capable of running software, and without limitation, ROM for storing digital signal processor (DSP) hardware, software. (ROM), RAM, and non-volatile memory are to be understood to implicitly include. Other hardware for the governor may also be included.

In the claims of this specification, components expressed as means for performing the functions described in the detailed description include all types of software including, for example, a combination of circuit elements or firmware / microcode, etc. that perform the functions. It is intended to include all methods of performing a function which are combined with appropriate circuitry for executing the software to perform the function. The invention, as defined by these claims, is equivalent to what is understood from this specification, as any means capable of providing such functionality, as the functionality provided by the various enumerated means are combined, and in any manner required by the claims. It should be understood that.

The above objects, features, and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Before describing the various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of construction and arrangement of components described in the following detailed description or illustrated in the drawings. The invention can be implemented and carried out in other embodiments and can be carried out in various ways. In addition, device or element orientation (e.g., "front", "back", "up", "down", "top", "bottom" The expressions and predicates used herein with respect to terms such as "," "left", "right", "lateral", etc. are used merely to simplify the description of the present invention, and related apparatus. Or it will be appreciated that the element does not simply indicate or mean that it should have a particular direction.

1 is a schematic configuration diagram of a unidirectional carbon fiber fabric weaving system according to a preferred embodiment of the present invention.

2 is a side cutaway view of the weaving system of FIG.

3 is a partially enlarged view for explaining the operation of the shuttle applied to the weaving system of FIG.

4 is a partially enlarged view showing a woven mesh structure made of continuous carbon fibers and warp yarns formed by the weaving system of FIG.

5 is a configuration diagram of an embodiment of the present invention.

Figure 6 is a view showing both the weft supply and the oblique supply of the present invention.

7 is a view mainly showing the weft supply of the present invention.

8 is a specific view of the weft supply unit of the present invention.

9 is a specific view of the guide needle of the present invention.

10 is a conceptual diagram of the dust measurement and alarm output of the present invention.

11 is a conceptual diagram of dust measurement of the present invention.

12 is a perspective view of a dust measuring device of the present invention.

Figure 13 is an exploded perspective view of the dust measuring apparatus of the present invention.

14 is a plan view of the dust measurement apparatus of the present invention.

15 is a conceptual view of the operation of the dust measuring apparatus of the present invention.

16 is a detailed view of a concave lens light collecting original of the present invention.

17 is an embodiment of a concave lens of the present invention.

18 is an exploded perspective view of the malodor chemical liquid applying device of the present invention.

19 is a cross-sectional view and a main portion cross-sectional view of the odor chemical liquid applying device of the present invention.

20 is an enlarged cross-sectional view of a main portion of the malodorous chemical liquid applying device of the present invention.

Figure 21 is a rotation motor and up and down drive cylinder configuration of the malodor chemical liquid applying apparatus of the present invention.

Figure 22 is an enlarged view of the main portion of the rotary motor and the vertical drive cylinder of the malodor chemical liquid applying apparatus of the present invention.

Figure 23 is a block diagram of the temporary fixing means of the malodor chemical solution coating apparatus of the present invention.

24 is another angle configuration diagram of the temporary fixing means of the malodor chemical solution coating device of the present invention.

25 is a configuration diagram of the hole for passing the chemical solution of the present invention,

First, referring to Figure 1, the present invention, the one-way carbon fiber fabric weaving system 10 is largely composed of an opener 100, a water spray unit 200, and a weaving device 300. In addition, the weaving device 300 is one or more feed rollers 320a, 320b for feeding the inclined supply unit 310 for supplying the inclined 312, and the inclined 312 supplied from the inclined supply unit 310 in the vertical direction ), A shuttle 330 for moving left and right so that the continuous carbon fiber 402 is hooked to the inclined 312 at regular intervals, and formed according to the left and right movement of the shuttle 330, and the continuous carbon fiber 402 is inclined. And a winding roller 340 for winding the fabric 500 of the mesh structure 312, and a controller 370 for controlling the operation of each component. On the other hand, the reference numeral 350 of FIG. 1 is an inclined frame of a structure in which a plurality of partitions are formed, the reference numeral 360 is a pair of open pins having different heights, and the reference numeral 380 is a continuous carbon fiber weft Surface density control device.

The unidirectional carbon fiber fabric weaving system 10 of the present invention is applicable to both oxidized fiber and carbon fiber as unidirectional carbon fiber. According to a preferred embodiment, the present invention is a one-way carbon fiber fabric weaving system 10 can be applied to the carbon fiber of 3K ~ 24K. For reference, since the carbon fiber has a sizing treatment on the surface thereof, it is not necessary to consider the problem of unwinding each filament strand constituting the carbon fiber according to the left and right reciprocating movement of the shuttle 330. However, in the case of the oxidized fiber, since the sizing treatment is not performed on the surface thereof, there may be a problem that each filament strand constituting the oxidized fiber is spread according to the left and right reciprocating movement of the shuttle 330. For example, while the oxygen fibers are moved to the weaving device, each of the filament strands constituting the oxygen fibers can be loosened and caught in the peripheral portion of the device, thereby causing problems in the process progress.

The opener unit 100 and the water spray unit 200 of the present invention, the one-way carbon fiber fabric weaving system 10 is the phenomenon that the filament strands of the one-way carbon fiber (for example, oxidized fiber or carbon fiber) is spread. It is a device element to prevent in advance.

The opener part 100 performs a function of preventing damage to the continuous carbon fiber 402 generated when the shuttle 330 moves. The opener part 100 is composed of, for example, a vertically bent 'b' shaped plate, and the cylindrical continuous carbon fiber bundle 400 is inserted into the flat part 100a of the 'b' shaped plate. I) a rotating shaft 102 is provided. In addition, the side portion 100b of the 'b' type plate is formed with a hole 104 through which the continuous carbon fiber yarn 402 supplied from the continuous carbon fiber bundle 400 is formed. Although not shown in the figure, since a bearing (not shown) is provided at the center of the planar portion 100a on which the rotating shaft 102 is installed, the rotating shaft 102 is provided with the continuous carbon fiber bundle 400 inserted therein. Rotate As a result, the unwinding of the continuous carbon fibers 402 drawn by the moving operation of the shuttle 330 can be smoothed, so that damage to the continuous carbon fibers 402 can be prevented primarily.

The water spraying unit 200 penetrates water into the continuous carbon fiber 402 passing through the hole 104 of the side part 100b to allow the filament strands constituting the continuous carbon fiber 402 to aggregate as much as possible. . The water injection unit 200 may be configured, for example, in a frame of a rectangular frame open to the outside. That is, the user may spray water directly from the water spraying unit 200 having a frame of a rectangular frame shape, for example, using a water spraying tool such as a sprayer, or may be separate from the upper portion of the frame of the rectangular frame shape. An automatic water spraying device (not shown) may be provided to automatically spray water onto the continuous carbon fiber 402 passing through the water spraying unit 200. Accordingly, the filament strands of the continuous carbon fibers 402 supplied to the weaving unit 300 can be aggregated to the maximum, thereby preventing the spread of the fibers completely.

The continuous carbon fiber 402 passing through the water spray unit 200 is supplied to the weaving device unit 300 as a weft through the shuttle 330.

The inclined supply portion 310 is a device element for supplying the inclined 312. Referring to FIG. 2, the warp feed part 310 is wound from the warp yarns 312 and gradually released to supply the warp yarns 312. The warp fiber bundle 311 and the warp fiber bundle 311 are supplied from the warp fiber bundle 311. It includes a guide pin 314 and a guide guide 316 for guiding the inclined 312. According to a preferred embodiment, polyester fiber may be used as the warp 312. The inclination supply part 310 continuously supplies the inclination 312 according to the rotation operation of the feed rollers 320a and 320b under the control of the controller 370.

The inclined 312 supplied from the inclined supply unit 310 (guide guide 316) passes through the inclined inlet frame 350 having a structure in which a plurality of partitions are formed, and then has two sets of opening pins having different heights ( Penetrates 360).

Two sets of opening pins 360 serve to separate the inclined 312 into the inclined upper layer and the inclined lower layer. Specifically, the two sets of opening pins 360 are spaced apart at regular intervals, for example, at an interval of 3 mm, and the opening pins 360 constituted by the first and second sets are respectively the first and second sets. The opening pins of the jaw are installed at different heights. That is, as shown in FIG. 3, an opening is formed by the inclined 312 passing through the first set of high pins 360a and the inclined 312 passing through the second set of low pins 360b and shuttles the opening. As the 330 passes, a mesh fabric woven 500 consisting of a continuous carbon fiber (weft) 402 and a warp 312 as shown in FIG. 4 is formed.

As shown in FIGS. 1 and 3, the shuttle 330 performs an operation of reciprocating left and right so that the continuous carbon fiber 402 is hung on the inclined 312 at regular intervals as described above. Since the structure of the shuttle 330 and its specific driving operations are already known, a detailed description thereof will be omitted.

The winding roller 340 winds up the fabric 500 of the mesh structure formed of the continuous carbon fiber 402 and the slope 312 formed according to the left and right movement operation of the shuttle 330.

Hereinafter, referring to Figures 1 to 4, it will be described a method for producing a unidirectional carbon fiber fabric using the present invention unidirectional carbon fiber fabric weaving system.

First, before driving the weaving system 10, the continuous carbon fiber bundle 400 is installed on the rotary shaft 102 of the opener 100, and then the end of the continuous carbon fiber yarn 402 is the hole 104 Through it to be coupled with the shuttle 330.

Next, after installing a plurality of inclined fiber bundle 311 in the inclined supply unit 310, each inclined fiber 312 is guide pin 314, and guide guide 316 of the inclined inlet frame 350 After penetrating each fine groove, it is installed so as to penetrate the opening pins of the first set 360a and the second set 360b at regular intervals. In addition, the end of the inclined 312 penetrating through the opening pins (360a, 360b) is to be coupled to the take-up roller (340).

Next, in accordance with the control signal of the controller 370, the inclination supply unit 310 supplies the inclination 312 at regular intervals in conjunction with the rotation of the feed rollers (320a, 320b) and the winding roller 340, the shuttle 330 ) Is a space between the inclined spaces 312 supplied in the weaving device 300 (ie, each of the opening fins of the first set 360a and the second set 360b) while performing a left-right reciprocating operation for a predetermined period. The continuous carbon fiber 402 penetrates into the space between each slope 312 formed by the same. At this time, the surface density is adjusted by adjusting the spacing of the continuous carbon fibers using the surface density adjusting device.

Accordingly, the continuous carbon fiber 402 is applied as the weft yarn, and a one-way carbon fiber fabric 500 having a constant surface density and a uniform arrangement is manufactured.

5 to 9 show, as an embodiment of the present invention, a frame body 600 through which a woven fabric is passed; An inclined supply unit 610 installed on an upper portion of the rear of the frame body and winding inclined and gradually releasing the inclined to supply the inclined; A weft supply unit 620 which is installed on one side of the frame body and gradually loosens the weft yarn for weaving and supplies the weft yarn; The inclined opening which divides the inclined from the inclined supply unit into two groups and moves the inclined of each group up and down so as to form an opening through which the weft yarns are introduced after each group is repeatedly opened in the opposite direction. Forming unit 630; A horizontal striking part 640 for advancing after weaving the weft yarn and striking the weft yarn which is entwined; A fabric winding unit 650 for winding the woven fabric while passing through the frame body; It comprises a shuttle 330 to transfer the weft supplied from the weft supply in a horizontal direction to induce the weaving operation is combined with the warp yarn is inclined; The weft supply unit 620 is provided by stacking a plurality of up, down, left, and right, and provided with a plurality of guide needles 660 for supplying the weft to the shuttle, the guide needle is selected to supply the weft to the shuttle 330. Is made.

That is, in the exemplary embodiment of the present invention, a plurality of weft feeders 620 and a plurality of guide needles 660 are provided, and the weaving operation is performed by selectively connecting the weft yarns to the shuttle by the guide needles 660.

That is, in the related art, there is a problem in that the whole work is stopped when the weft thread is broken because it is provided with one weft supply part and one guide needle, but the present invention includes a plurality of weft supply parts, and the weft supply part of the weft feeder in the shuttle If the weft in one weft feed means is cut off because there are a plurality of guide needles for relaying, weaving work is continued without interruption because weaving the weft in the other weft feed means connects the guide needle with a shuttle. There is a feature that can be implemented as.

In other words, the present invention is provided with a total of five weft feed section 620 and five guide needles 660, it is possible to specify the appropriate number of weft supply, and as soon as the weft is cut, weft of the other weft feeder To the shuttle via the guide needle can continue the weaving operation.

In the embodiment of the present invention, the two weft feeder and two guide needles are operated so that two strands of weft are supplied to the weaving device, and if the currently operating weft feeder is broken or the material of the weft feeder is different. If it falls, another weft feeder can be used to immediately resume weaving.

On the other hand, the present invention is installed by further adding a dust measuring means (1000a) to one side of the frame body 600, the alarm signal output unit 1100 when it is determined that there is dust above the reference as a result of the measurement of the dust measuring means (1000a) Alarm signal is output through) to induce appropriate evacuation if there is any worker nearby.

The dust measuring means 1000a of the present invention includes a housing 4 for collecting dust and a wire mesh 10a installed inside the housing 4 to remove moisture from the input dust so that only accurate dust passes. And a wire mesh rotating motor 10b for inserting and coupling the wire mesh and rotating the wire mesh to accelerate the removal of moisture present in the air, and a heater to supply heat to the wire mesh to rapidly evaporate moisture contacting the wire mesh. Heater means for providing heat for providing heat (10c), infrared ray transmitting means (A) for emitting infrared rays to detect the dust from which moisture has been removed, and positioned opposite to the infrared ray transmitting means Infrared receiving means (B) for receiving the light emitted from the means and determining the inflow of dust according to the degree of the received amount, and the output voltage of the infrared receiving means (B) Is smaller than the set value comprises a dust control measures (C) for controlling so that the input voltage is increased in the infrared transmitting section (A).

The wire mesh (10a) is required to be coupled to the vertical guide rod (10a-2) coupled to the horizontal guide rod (10a-1) and the vertical groove (5) of the housing to be detachable to the shaft of the wire mesh rotary motor (10b) The horizontal guide rod 10a-1 is separated from the wire mesh rotation motor 10b and at the same time, the vertical guide rod 10a-2 is separated from the housing 4 to remove contaminants.

And, on one side of the housing further installed a humidity sensor (7) to control the rotational speed of the wire mesh rotary motor (10b) according to the humidity, if the humidity is high, the rotational speed of the wire mesh rotary motor (10b) higher than the reference and at the same time than the reference When high heater heat is supplied and humidity is low, the rotation speed of the wire mesh rotating motor 10b is lowered than the reference and at the same time, the heater heat is supplied to the heater heat lower than the reference.

Then, the infrared ray transmitting means (A) receives the infrared ray transmission control signal from the dust measurement control unit (C) to determine the infrared ray amount and outputs the changed infrared ray amount.

That is, when the resultant value of the infrared receiver B is transmitted to the dust measurement controller C, the dust measurement controller C predicts the dust generation amount based on the data of the infrared receiver B, and according to the dust generation amount. By outputting a control signal to the infrared transmitting means (A) to control the amount of infrared transmission to guide the output.

That is, the dust measurement control unit C reads the light amount data output from the infrared receiving unit B, and automatically controls the light amount of the infrared light emitting unit on the basis of this, so that the sensitivity control is automatically kept constant so that the contamination situation due to the dust Even in dust detection, the optimum sensitivity is maintained so that measurements can be made.

In other words, the dust measurement control unit C determines that the pollution degree is high when the amount of received light from the infrared receiver B is weak, and outputs a control signal to increase the amount of light from the infrared transmitter A for more accurate dust measurement. And, if the received light amount of the infrared receiver means (C) is too high, since there is no contamination or it is difficult to precisely measure, the control signal is output to lower the amount of light from the infrared transmitter (A). In other words, it is necessary to maintain the amount of infrared ray transmitting light in an appropriate state. Only then, the amount of infrared radiation measured by the infrared receiver can be accurate, so that dust generation can be predicted more precisely. Therefore, the dust amount data measured by the dust measurement control unit of the present invention can output a dust measurement result of high reliability.

Infrared transmission means (A) of the present invention,

A concave lens mounting disc 1 for mounting a plurality of concave lenses to limit the output of infrared rays,

An infrared transmitting element (2) for outputting infrared rays in proximity to one of the plurality of concave lenses;

A disc drive motor (3) coupled to the center of the disc for mounting the concave lens and driving the disc for mounting the concave lens in a clockwise or counterclockwise direction to locate a lens having a different depression angle in the infrared transmitting element;

It is electrically coupled to the disc drive motor, and if the amount of dust is small, the disc is driven so that infrared rays pass through the lens with a low depression angle, so that the infrared transmitting element is controlled to be positioned at the lens with a low depression angle, and when the amount of dust is large, It includes a transmission control unit for controlling the infrared transmission element is positioned in the lens with a high depression angle by driving the disc so that the infrared ray passes through the high angle lens.

The present invention configured as described above is to flow the concave lens mounting disc to more accurately determine the dust concentration.

Referring to the actual operation, first, light of the transmitting element is output through the third concave lens 1c installed at the center of the concave lens group 1.

When the concentration of dust decreases, the second concave lens 1b positioned at the right side of the third concave lens 1c and having a depression angle lower than that of the third concave lens 1c comes to the position of the transmitting element. The light output of the transmitting element 2 is lowered and output. In addition, when the dust concentration increases further, the first concave lens having a depression angle lower than that of the second concave lens comes to the position of the transmitting element, thereby lowering the light output of the transmitting element and outputting it.

When the dust concentration increases, the fourth concave lens 1d positioned at the left side of the third concave lens 1c and having a depression angle higher than that of the third concave lens 1c comes to the position of the transmitting element 2. Accordingly, the light output of the transmitting element 2 is increased to output. In addition, when the concentration of monji is further lowered, a fifth concave lens positioned at the left side of the fourth concave lens and having a depression angle higher than that of the fourth concave lens is placed at the position of the transmitting element, thereby increasing the light output of the transmitting element much higher. Will print.

In addition, the concave lens group is designed to vary the degree of output of the infrared light according to the depression angle of the center portion, the third concave lens (1c) is basically installed at the center of the operating rod to form a depression angle of 25 degrees.

The second concave lens 1b is used when the infrared light needs to be slightly reduced and output. The second concave lens 1b is provided on the right side of the third concave lens 1c to form a depression angle of 15 degrees.

In addition, the first concave lens 1a is used when the infrared light is to be reduced and output more, and is installed on the right side of the second concave lens 1b to form a depression angle of 5 degrees.

In addition, the fourth concave lens 1d is used in the case where the infrared light is to be further raised and output, and the fourth concave lens 1d is installed on the left side of the third concave lens 1c to form a depression angle of 35 degrees.

In addition, the fifth concave lens 1e is used in the case where the infrared light needs to be increased to output more, and is installed on the left side of the fourth concave lens 1d to form a depression angle of 45 degrees.

On the other hand, the present invention includes a malodor chemical liquid applying device 1100 as the alarm signal output means, if the fine dust is more than the reference outputs malodor from the malodor chemical liquid applying device 1100 to force the operator away from the device.

That is, the dust measuring means (1000a) is electrically connected to the odor chemical liquid applying device for applying the odor to the outside in accordance with the control signal of the dust measuring means further comprises, in order to protect the operator if the fine dust is higher than the standard It will output odor.

The malodor chemical applying device 1100 includes a housing 1110, a battery 1120, a rotating motor 1130, a vertical drive cylinder 1140, a lifting and lowering support spring 1150, and a malodor drug applicator. 1160, a chemical liquid storage means 1170, and an applicator temporary fixing means 1180.

The housing 1110 has a space therein and includes various devices. That is, the housing is configured by bonding two cases each of which is open at one side, and the various devices are installed in the space portion generated in the process of bonding the case. Such a housing is generally similar in structure to means having space therein.

The battery 1120 is installed inside the housing 1110 and serves to provide electricity to the device after charging the electricity by receiving power from the outside. That is, the battery is installed on the upper portion of the housing and is electrically connected to an external power supply device to receive electricity, and temporarily store the supplied power to supply electricity to various devices requiring power.

The rotary motor 1130 is electrically connected to the battery and receives power from the battery to convert it into a mechanical rotational motion to freely rotate the motor shaft. At this time, the motor shaft 1131 has a shape in which the bottom surface is formed in a waveform form in the vertical direction and the curved waveform form continuously rotates. That is, the rotary motor is rotated by receiving power from the battery, the bottom surface of the motor shaft is made of a curved waveform form to rotate.

The up and down drive cylinder 1140 is mechanically connected to the rotary motor, and flows while moving up and down by switching the rotation of the rotary motor to reciprocating vertical movement. At this time, the rotating shaft 1141 of the up and down drive cylinder 1140 has a waveform shape in the vertical direction and performs the lifting and lowering operation while repeating the mutual coupling and separation with the waveform of the motor shaft of the rotating motor. That is, the up and down drive cylinder is made in the form of a curved waveform of the rotating shaft in the same way as the motor shaft of the rotary motor so that the lifting and lowering operation is performed according to the rotation of the rotary motor, so that the up and down driving cylinder moves up and down when the rotating motor rotates Will be

The elevating support for the spring spring 1150 is installed on the outer periphery of the up and down drive cylinder 1140, one side is fixed to the locking jaw of the housing 1110 and the other side is fixed to the locking jaw of the up and down driving cylinder 1140 The vertical drive cylinder 1140 is elastically supported so that the vertical drive cylinder 1140 maintains the lifting operation. That is, the elevating support spring shot 1150 has a shot action to continuously push up and down the driving cylinder 1140 in the upper direction, so that the rotary motor 130 and the waveform of the motor shaft 1131 of the rotating motor when rotating The up and down drive cylinder is lowered while the waveform of the rotary shaft 1141 of the up and down drive cylinder 1140 is staggered, and the up and down drive cylinder 1140 is raised by the elevating support spring 1150 after the staggering is completed, The waveform of 1141 and the waveform of the motor shaft 1131 of the rotating motor 1130 are in close contact with each other. Therefore, the vertical drive cylinder 1140 is repeated close to and spaced apart from the rotary motor 1130, so that the vertical drive cylinder 1140 is vertically moved around the rotary motor 1130.

The malodor drug applicator 1160 is formed in a body cylinder shape and a plurality of malodorous drug passage holes 1161 are installed at the bottom thereof, and are inserted into and coupled to the upper and lower drive cylinders 1140 to supply malodorous drugs. Play a role. That is, the odor drug applicator 1160 discharges the odor drug stored therein to the outside through the odor drug passage hole 1161, and the odor drug applicator 1160 is installed inside the vertical drive cylinder. Therefore, the odor drug applicator 1160 is blown during the vertical operation of the vertical drive cylinder 1140 to output the drug to the outside according to the law of inertia.

The malodor chemical storage means 1170 is a state in which the malodorous drug is stored therein, is inserted into the malodorous drug applicator 1160 is output through the malodorous drug passage hole 1161 of the malodorous drug applicator 1160. . That is, the malodor chemical storage means 1170 is a state in which the drug is stored, and the lower portion is coupled to the malodor drug applicator 1160 in an open form, and the odor of the malodor chemical storage means when the upper and lower drive cylinders 1140 are driven. The drug is output to the outside. In fact, because the malodorous drug passage hole 1161 is finely formed, it is not easily discharged to the outside when the vertical driving cylinder 1140 is not operated.

The odor drug applicator temporary fixing means 1180 is coupled to one end of the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, the upper and lower drive cylinder 1140 and the housing 1110 The odor drug applicator 1160 is temporarily fixed at the same time to prevent the odor drug applicator 1160 from falling down due to gravity action while the up and down drive cylinder 1140 and the odor drug applicator 1160 flow upward and downward. When the odor drug applicator 1160 is replaced, the odor drug applicator is released by pressing a button so that the odor drug applicator is detached from the up-down driving cylinder and removed downward. That is, the odor drug applicator temporary fixing means temporarily fixes the upper and lower drive cylinders and the odor drug applicator to prevent the odor drug applicator from being removed during operation, and after using all the drugs present in the odor drug applicator, the button is pressed. Press to release the malodor drug applicator and reinduce the malodor chemical storage means.

The temporary fixing means 1180 includes a hook 1118, a connection piece 1182, a rotation support hinge 1183, a support spring 1184, a sliding flow piece 1185, and a push button (1). 1186).

The hook hook 1181 is formed in the shape of a sharp wedge end is forced through the coupling hole (1140a) and the coupling hole (1160a) of the drug applicator (1160) up and down driving cylinder (1140) to apply odor drug The machine 1160 maintains the state coupled to the inner circumference of the vertical drive cylinder 1140.

The connecting piece 1182 is integrally connected to the hooking hook 1181 in an oblique direction and guides the hooking hook 1181 to move clockwise or counterclockwise by a rotational movement.

The rotatable support hinge 1183 is installed between the connecting piece 1182 and the locking hook 1181 and serves as a central axis to which the connecting piece is rotated.

The support spring 1184 is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the locking hook 1181 flows counterclockwise so that the drug applicator is coupled to the vertical driving cylinder. When the connecting piece is pressed by the external force and pressed in the direction of the up-down driving cylinder, the hook hook 1181 is separated from the up-down driving cylinder 1140 and the odor drug applicator 1160 while maintaining the state. The applicator 1160 is guided to be removed from the vertical drive cylinder 1140.

The sliding flow piece 1185 is installed at the end of the connecting piece 1182 and moves simultaneously when the hook 1118 and the connecting piece 1182 move up and down in accordance with the vertical flow of the vertical driving cylinder 1140.

The push button 1186 is slidingly coupled with the sliding flow piece 1185 to support the vertical movement of the sliding flow piece 1185, and when the odor drug applicator 1160 is replaced, in the direction of the vertical drive cylinder 1140. By pushing the connecting piece 1182, the connecting piece 1182 rotates about the hinge pin 1183 for rotational support, so that the hook 1118 is moved from the up-and-down cylinder 1140 and the odor drug applicator 1160. While being separated, the odor drug applicator 1160 functions to induce removal from the vertical drive cylinder 1140.

10: one-way carbon fiber fabric weaving system 100: opener
100a: flat part 100b: side part
200: water spray unit 300: weaving device unit
310: warp feed part 311: warp fiber bundle
312: slant 320a, 320b: feed roller
330: shuttle 340: winding roller
350: inclined frame 360: opening pin
370: controller 380: surface density control
400: continuous carbon fiber bundle 402: continuous carbon fiber yarn

Claims (6)

A frame body 600 through which the woven fabric is passed;
An inclined supply unit 610 installed on an upper portion of the rear of the frame body and winding inclined and gradually releasing the inclined to supply the inclined;
A weft supply unit 620 which is installed on one side of the frame body and gradually loosens the weft yarn for weaving and supplies the weft yarn;
The inclined opening which divides the inclined from the inclined supply unit into two groups and moves the inclined of each group up and down so as to form an opening through which the weft yarns are introduced after each group is repeatedly opened in the opposite direction. Forming unit 630;
A horizontal striking part 640 for advancing after weaving the weft yarn and striking the weft yarn which is entwined;
A fabric winding unit 650 for winding the woven fabric while passing through the frame body;
It comprises a shuttle 330 to transfer the weft supplied from the weft supply in a horizontal direction to induce the weaving operation is combined with the warp yarn is inclined;
The weft supply unit 620 is provided by stacking a plurality of up, down, left, and right, and provided with a plurality of guide needles 660 for supplying the weft to the shuttle, the guide needle is selected to supply the weft to the shuttle 330. To be made;

Dust measuring means (1000a) installed on one side of the frame body to measure dust generated around the frame body;
And a odor spreading device (1100) electrically connected to the dust measuring means and outputting odor to the outside according to a control signal of the dust measuring means. delete The method of claim 1,
The dust measuring means,
A housing 4 for collecting dust, a wire mesh 10a installed inside the housing 4 to remove moisture from the input dust to guide only the correct dust, and inserting and combining the wire mesh Wire mesh rotary motor (10b) for rotating the water to accelerate the removal of water present in the air, and electric means for providing a heater heat to supply the heat to the wire mesh by supplying heat to the wire mesh to rapidly evaporate moisture 10c, infrared ray transmitting means (A) for emitting infrared rays to detect the dust from which the moisture has been removed, and positioned to face the infrared ray transmitting means and receiving and receiving the light emitted from the infrared ray transmitting means. If the output voltage of the infrared receiver means (B) and the infrared receiver means (B) for determining the dust inflow according to the amount of the amount is smaller than the set value, It is achieved by including a dust control measures (C) for controlling so that the input voltage of the transmission line means (A) increases;
One side of the housing further installed a humidity sensor (7) by the dust measurement control unit (C) according to the humidity to control the rotation speed of the wire mesh rotary motor (10b) if the humidity is high based on the rotation speed of the wire mesh rotary motor (10b) The fabric weaving system, characterized in that the supply of heater heat higher than the reference at the same time higher and lower humidity, and lower the rotation speed of the wire mesh rotary motor (10b) than the reference and at the same time supplying the heater heat lower than the reference. The method of claim 3, wherein
The wire mesh (10a) is required to be coupled to the vertical guide rod (10a-2) coupled to the horizontal guide rod (10a-1) and the vertical groove (5) of the housing to be detachable to the shaft of the wire mesh rotary motor (10b) Characterized in that the horizontal guide rod (10a-1) is separated from the wire mesh rotary motor (10b) and at the same time the vertical guide rod (10a-2) from the housing (4) to remove contaminants present in the wire mesh Fabric weaving system. The method of claim 1,
The odor spreading device 1100,
A housing 1110;
A battery 1120 installed inside the housing 1110 and receiving electricity from the outside to charge electricity and provide electricity to the device;
A rotation motor 1130 electrically connected to the battery and receiving power from the battery and converting the same into mechanical rotational motion;
A motor shaft 1131 which is installed on the central axis of the rotary motor and rotates in correspondence with the rotation of the rotary motor, the bottom surface of which is in the form of a waveform;
A vertical drive cylinder 1140 positioned at a lower end of the rotary motor and flowing while moving up and down by converting rotation of the rotary motor into a reciprocating vertical motion;
Located in the upper portion of the vertical drive cylinder 1140, but is located on the central axis, while being in mechanical contact with the motor shaft 1131 of the rotary motor 1130, coupled with the motor shaft 1131 of the rotary motor 1130 And a rotation shaft 1141 which moves up and down while repeating separation.
It is installed on the outer periphery of the up and down drive cylinder 1140, one side is fixed to the locking jaw of the inner housing and the other side is fixed to the locking jaw of the up and down drive cylinder to support the up and down drive cylinders to maintain the up and down drive cylinder to move up and down Elevating support springs (1150) to be able to support;
Inserted and coupled to the inside of the up and down drive cylinder 1140, the cylinder shape as a whole, and a plurality of drug passing holes (1161) is provided on the bottom, it is made to supply the drug while flowing up and down according to the movement of the up and down drive cylinder Malodor drug applicator 1160;
One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the odor drug applicator 1160 by temporarily fixing the upper and lower drive cylinders and odor drug applicator 1160 at the same time based on the housing And odor drug applicator temporary fixing means (1180) to prevent the drop down by gravity action. The method of claim 5,
The odor drug applicator temporary fixing means 1180,
The hook is formed in the shape of a sharp wedge and is forcibly fitted through the coupling hole of the up-and-down cylinder and the drug applicator so that the odor drug applicator is kept connected to the inner circumference of the up-down cylinder. Wow;
A connecting piece 1182 which is integrally connected to the hooking hook 1181 in a diagonal direction and guides the hooking hook 1181 to move in a clockwise or counterclockwise direction by a rotational movement;
A rotation support hinge 1183 installed between the connection piece 1182 and the hook hook 1181 to support the connection piece being rotated;
It is installed between the connecting piece 1182 and the up and down drive cylinder 1140 and pushes the connecting piece outwards so that the hook hook 1181 flows in a counterclockwise direction to maintain the drug applicator coupled to the up and down drive cylinder. When the connection piece is pressed by the external force and compressed in the vertical drive cylinder direction, the hook 1118 is separated from the vertical drive cylinder 1140 and the drug applicator 1160 while the drug applicator 1160 is vertically driven cylinder. A support spring 1184 for inducing removal from the nozzle 1140;
A sliding flow piece (1185) installed at the end of the connecting piece (1182) and simultaneously moving when the hook (1181) and the connecting piece (1182) move up and down in accordance with the vertical flow of the vertical drive cylinder (1140);
Slidingly coupled with the sliding flow piece 1185 to support the vertical movement of the sliding flow piece 1185, push the odor drug applicator 1160 toward the vertical drive cylinder 1140 at the time of replacement, the connection piece 1118 By pressing, the connecting piece 1182 rotates about the hinge pin 1183 for rotational support so that the hook 1118 is separated from the upper and lower driving cylinders 1140 and the drug applicator 1160 while the odor drug applicator 1160 is applied. Fabric push system comprising a push button (1186) to guide the removal from the vertical drive cylinder (1140).

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