CN112726078A

CN112726078A - Fiber cloth spinning device

Info

Publication number: CN112726078A
Application number: CN202011507699.2A
Authority: CN
Inventors: 王秀珠
Original assignee: Changle Zhiyuan Technology Development Co ltd
Current assignee: Changle Zhiyuan Technology Development Co ltd
Priority date: 2020-12-18
Filing date: 2020-12-18
Publication date: 2021-04-30

Abstract

The invention discloses a fiber cloth weaving device, comprising: the cooling box body is provided with a fiber cloth inlet and a fiber cloth outlet at two ends respectively, a textile machine body and a fiber cloth collecting roller are arranged at two sides of the cooling box body close to the fiber cloth inlet and the fiber cloth outlet respectively, a first roller set and a second roller set are arranged in the cooling box body and are located on different horizontal planes respectively, the first roller set and the second roller set respectively comprise a plurality of rollers which are arranged in parallel, the rollers are of hollow structures and are internally provided with cavities, two ends of each roller are respectively provided with a sealing rotating shaft I and a sealing rotating shaft II which are connected with the side wall of the cooling box body, a hollow hole is formed in the central axis of the sealing rotating shaft I, and the holes are communicated with the cavities; a coolant circulation assembly; and a cold air assembly. This device can improve the work efficiency of fibre cloth cooling, improves production efficiency.

Description

Fiber cloth spinning device

Technical Field

The invention relates to the technical field of spinning. More particularly, the present invention relates to a fiber cloth weaving apparatus.

Background

The fiber cloth is also called carbon fiber cloth, carbon fiber fabric and the like, and is internationally called as a third-generation material after being used for stone devices, steel and other metals because the fiber cloth is a composite material made of carbon fibers, has extremely high strength, is ultralight, and is resistant to high temperature and high pressure. The fiber cloth is firstly heated in the production process, and then the fibers are woven by the spinning device, so that the produced fiber cloth also has certain heat, and if the produced fiber cloth is directly discharged and stored in the fiber cloth storage device after being produced, the residual heat of the fiber cloth can lead the adjacent fiber cloth to be adhered. The fiber cloth weaving device in the prior art is low in cooling speed and production efficiency, and easily causes the problems of deformation and the like of produced fiber cloth.

Disclosure of Invention

The invention aims to provide a fiber cloth spinning device which is high in cooling speed and high in production efficiency.

To achieve these objects and other advantages in accordance with the purpose of the invention, according to one aspect of the invention, there is provided a fiber cloth weaving apparatus comprising:

the cooling box body is provided with a fiber cloth inlet and a fiber cloth outlet at two ends respectively, a textile machine body and a fiber cloth collecting roller are arranged at two sides of the cooling box body close to the fiber cloth inlet and the fiber cloth outlet respectively, a first roller set and a second roller set are arranged in the cooling box body and are located on different horizontal planes respectively, the first roller set and the second roller set respectively comprise a plurality of rollers which are arranged in parallel, the rollers are of hollow structures and are internally provided with cavities, two ends of each roller are respectively provided with a sealing rotating shaft I and a sealing rotating shaft II which are connected with the side wall of the cooling box body, a hollow hole is formed in the central axis of the sealing rotating shaft I, and the holes are communicated with the cavities;

coolant liquid circulation subassembly, it includes circulating pump, feed liquor pipeline, a plurality of cooling subassembly and returns the liquid pipeline, the cooling subassembly includes outer tube and the inner tube of coaxial setting, the length of outer tube is less than the length of inner tube, the outer pipe box is established the periphery of inner tube, the outer tube is provided with open end and blind end, the open end through a plurality of bracing pieces with the lateral wall of inner tube is connected, the open end of outer tube is passed sealed pivot I's hole, the lateral wall of outer tube pass through sealed bearing with the lateral wall of hole is connected, makes sealed pivot I can be relative the sealed rotation of outer tube, the inner tube stretches into in the cavity, the inner tube of each cooling subassembly all communicates the feed liquor pipeline, the outer tube of each cooling subassembly all communicates returns the liquid pipeline, circulating pump, feed liquor pipeline, inner tube, outer tube, liquid pipeline, liquid return pipeline, The circulating pumps are connected in sequence to form a cooling liquid circulating pipeline; and the number of the first and second groups,

the cold wind subassembly, it includes roof, bottom plate and fan, the roof sets up cooling box top, the bottom plate sets up cooling bottom of the case portion, all be provided with the ventilation chamber in roof and the bottom plate, the lower surface of roof with the upper surface of bottom plate all is provided with the ventilation hole intercommunication the ventilation chamber, the fan passes through air pipe connection the ventilation chamber.

Further, the inner pipe extends into the cavity from 2/3 to 5/6.

Furthermore, a plurality of rollers are respectively provided with a synchronizing wheel, and the synchronizing wheels are connected with a driving motor through a synchronous belt.

Furthermore, the first roller group is located above the second roller group, and the fiber cloth sequentially bypasses the first roller group from one side and then sequentially bypasses the second roller group from the same side.

Furthermore, a floatable blocking piece is arranged at the position of the vent hole in the upper surface of the bottom plate, the blocking piece comprises a disc-shaped baffle plate, a connecting rod and a cross-shaped support, two ends of the connecting rod are respectively connected with the baffle plate and the support, the baffle plate is located above the vent hole, the support is located below the vent hole, the connecting rod penetrates through the vent hole, and the diameter of the baffle plate and the width of the support are both larger than the diameter of the vent hole.

Further, the stopper is made of a lightweight material.

The invention at least comprises the following beneficial effects: according to the invention, two groups of rotating rollers are arranged in the cooling box body, and the fiber cloth sequentially bypasses the first rotating roller group from one side and then sequentially bypasses the second rotating roller group from the same side, and is matched with the cold air assembly to convey cold air from the top and the bottom of the cooling box body, so that the cold air cooling is conveniently and rapidly carried out on the front and back surfaces of the fiber cloth; the rotary roller is of a hollow structure, the cavity inside the rotary roller is communicated with the cavity, and the cooling liquid is used for cooling the fiber cloth when the fiber cloth rotates on the rotary roller. The invention combines cold air and cooling liquid to carry out all-round cooling on the fiber cloth, accelerates the cooling rate of the fiber cloth and improves the production efficiency.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

FIG. 1 is a schematic structural diagram of one embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the cooling box of the present invention;

FIG. 3 is a schematic view of the construction of the roll according to the invention;

FIG. 4 is a schematic structural view of a coolant circulation assembly according to the present invention;

FIG. 5 is a schematic structural diagram of a stopper according to the present invention.

Detailed Description

The present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.

It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

As shown in fig. 1 to 4, the present application provides a fiber cloth weaving device, including: the cooling device comprises a cooling box body 100, wherein a fiber cloth inlet 101 and a fiber cloth outlet 102 are respectively arranged at two ends of the cooling box body 100, a textile machine body 400 and a fiber cloth collecting roller 500 are respectively arranged at two sides of the cooling box body 100 close to the fiber cloth inlet 101 and the fiber cloth outlet 102, a first roller set and a second roller set are respectively arranged in the cooling box body 100 and are respectively positioned on different horizontal planes, the first roller set and the second roller set both comprise a plurality of parallel rollers 103, each roller 103 is of a hollow structure and is internally provided with a cavity 104, a sealing rotating shaft I105 and a sealing rotating shaft II 106 are respectively arranged at two ends of each roller 103 and are connected with the side wall of the cooling box body 100, a hollow hole is formed in the central axis of each sealing rotating shaft I105, and the holes are communicated with the cavities 104;

cooling liquid circulation subassembly 200, it includes circulating pump 201, feed liquor pipeline 202, a plurality of cooling subassembly 210 and returns liquid pipeline 203, cooling subassembly 210 includes outer tube 211 and inner tube 212 of coaxial setting, the length of outer tube 211 is less than the length of inner tube 212, outer tube 211 cover is established the periphery of inner tube 212, outer tube 211 is provided with open end and blind end, the open end through a plurality of bracing pieces 213 with the lateral wall of inner tube 212 is connected, the open end of outer tube 211 passes the hole of sealed pivot I105, the lateral wall of outer tube 211 pass through sealed bearing with the lateral wall of hole is connected, makes sealed pivot I105 can be relative outer tube 211 seals the rotation, inner tube 212 stretches into in the cavity 104, the inner tube 212 of each cooling subassembly 210 all communicates feed liquor pipeline 202, the outer tube 211 of each cooling subassembly 210 all communicates return liquid pipeline 203, the circulating pump 201, the liquid inlet pipeline 202, the inner pipe 212, the outer pipe 211, the liquid return pipeline 203 and the circulating pump 201 are sequentially connected to form a cooling liquid circulating pipeline; and the number of the first and second groups,

cold wind subassembly 300, it includes roof 301, bottom plate 302 and fan 303, roof 301 sets up cooling box 100 top, bottom plate 302 sets up cooling box 100 bottom, all be provided with the ventilation chamber in roof 301 and the bottom plate 302, the lower surface of roof 301 with the upper surface of bottom plate 302 all is provided with ventilation hole 310 intercommunication the ventilation chamber, fan 303 passes through ventilation pipe 304 and connects the ventilation chamber.

In the above embodiment, the textile machine body 400, the cooling tank 100, and the fiber cloth collecting roller 500 are provided, and the fiber cloth spun by the textile machine body 400 is cooled in the cooling tank 100 and finally collected by the fiber cloth collecting roller 500. The fiber cloth inlet 101 and the fiber cloth outlet 102 for the fiber cloth to enter and exit are arranged on the side walls of the left end and the right end of the cooling box body 100, two rows of rotating rollers, namely a first rotating roller group and a second rotating roller group, are arranged in the cooling box body 100, each rotating roller group comprises a plurality of rotating rollers 103 which are parallel to each other, each rotating roller 103 is of a hollow structure, two ends of each rotating roller 103 are connected with the front side wall and the rear side wall of the cooling box body 100 through a sealing rotating shaft I105 and a sealing rotating shaft II 106, wherein holes are arranged on the axes of the plurality of sealing rotating shafts I105 on the same side wall of the cooling box body 100 and communicated with a cavity 104 of the rotating roller 103, an outer pipe 211 is coaxially arranged in each hole in a penetrating way, a sealing bearing is arranged between the inner wall of each hole and the outer wall of the outer pipe 211, so that the sealing rotating shaft I105 can rotate relative to the outer pipe 211, an inner pipe, inner tube 212 one end surpasss outer tube 211 and stretches into in the cavity 104 of rotating roller 103, and the other end passes outer tube 211 intercommunication inlet conduit 202, inner tube 212 intercommunication liquid return pipe 203, be connected with circulating pump 201 between inlet conduit 202 and the liquid return pipe 203. In addition, a top plate 301 and a bottom plate 302 with ventilation cavities are installed on the top and the bottom of the cooling box body 100, ventilation holes 310 are formed in the surfaces of the top plate 301 and the bottom plate 302, the ventilation cavities and the interior of the cooling box body 100 are communicated through the ventilation holes 310, and a fan 303 blows air into the ventilation cavities through a ventilation pipeline 304. According to the invention, the upper and lower groups of rotating rollers are arranged in the cooling box body 100, and the fan 303 is combined with the cold air component 300 to ventilate the ventilation cavity through the ventilation pipeline 304, so that cold air is ventilated into the box body through the top plate 301 and the bottom plate 302, the front surface and the back surface of the fiber cloth can both receive the cold air, the cooling speed of the fiber cloth is improved, and the fiber cloth is uniformly cooled. The inside of commentaries on classics roller 103 sets up cavity 104, inner tube 212 stretches into the transport of cavity 104 inside carrying out the coolant liquid, flows to liquid return pipe 203 through outer tube 211 after cavity 104 is filled up to the coolant liquid afterwards, circulating pump 201 is connected liquid return pipe 203 and inlet conduit 202 form the circulation path of coolant liquid, and the fibre cloth contacts with commentaries on classics roller 103, gives the commentaries on classics roller 103 with heat transfer, and the coolant liquid in cavity 104 carries out the heat exchange with commentaries on classics roller 103, cools down the fibre cloth, and the coolant liquid in inner tube 212 carries out the heat exchange with the coolant liquid in cavity 104 simultaneously, cools down the coolant liquid in the cavity 104, makes the coolant liquid temperature in the cavity 104 even, avoids changeing the temperature difference at roller 103 both ends great, makes the fibre cloth cooling inhomogeneous. In addition, the fiber cloth is cooled in an all-dimensional manner by combining cold air with cooling liquid, so that the cooling rate of the fiber cloth is increased, and the production efficiency is improved.

In other embodiments, as shown in fig. 3 to 4, the inner tube 212 extends into the cavities 104 from 2/3 to 5/6. The inner tube 212 stretches into the cavity 104, the coolant liquid enters the cavity 104 bottom of the rotating roller 103 through the inner tube 212, the whole cavity 104 is filled with gradually, then the liquid return pipeline 203 is conveyed out by the outer tube 211, the coolant liquid in the cavity 104 cools the fiber cloth on the surface of the rotating roller 103, the heat exchange process is carried out, meanwhile, the coolant liquid in the inner tube 212 exchanges heat with the coolant liquid in the cavity 104, thereby the temperature of the coolant liquid in the cavity 104 is even, the uniform cooling of the fiber cloth is realized, the temperature difference between two ends of the rotating roller 103 is avoided being large, and the fiber cloth is cooled unevenly.

In other technical schemes, a plurality of rollers 103 are respectively provided with a synchronizing wheel, and the synchronizing wheels are connected with a driving motor through a synchronous belt. The driving motor drives the plurality of rollers 103 to synchronously rotate through the synchronous belt, so that the fiber cloth is convenient to convey.

In other embodiments, as shown in fig. 1, the first roller set is located above the second roller set, and the fiber cloth sequentially passes around the first roller set from one side and then sequentially passes around the second roller set from the same side. Fibre cloth is on first roller set, and the upper surface of the cold wind direct-blowing fibre cloth that roof 301 leads to, when fibre cloth is on second roller set, the lower surface of the cold wind direct-blowing fibre cloth that bottom plate 302 lets in is convenient for carry out the cooling of full aspect to fibre cloth, improves cooling rate.

In other technical solutions, as shown in fig. 5, a floatable stopper 305 is disposed at a vent hole 310 on the upper surface of the bottom plate 302, the stopper 305 includes a disc-shaped baffle plate 306, a connecting rod 307 and a cross-shaped bracket 308, two ends of the connecting rod 307 are respectively connected to the baffle plate 306 and the bracket 308, the baffle plate 306 is located above the vent hole 310, the bracket 308 is located below the vent hole 310, the connecting rod 307 passes through the vent hole 310, and both a diameter of the baffle plate 306 and a width of the bracket 308 are larger than a diameter of the vent hole 310. The blocking piece 305 is arranged, the baffle 306 is positioned on the vent hole 310, the bracket 308 is positioned below the vent hole 310, the connecting rod 307 is connected between the baffle 306 and the bracket 308, the baffle 306 is blown by wind during ventilation, the bracket 308 is limited below the vent hole 310, and the baffle 306 is buckled on the vent hole 310 during non-ventilation, so that foreign matters in the cooling box body 100 are prevented from falling into the vent hole 310 to block the ventilation pipeline 304.

In other embodiments, the stop 305 is made of a lightweight material. The stop 305 is relatively light to facilitate blowing it up during ventilation.

The number of apparatuses and the scale of the process described herein are intended to simplify the description of the present invention. Applications, modifications and variations of the fiber cloth weaving apparatus of the present invention will be apparent to those skilled in the art.

While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims

1. Fibre cloth weaving device, its characterized in that includes:

2. A cloth weaving device as claimed in claim 1 wherein the inner tube extends into the cavity 2/3 to 5/6.

3. The fiber cloth weaving apparatus of claim 1, wherein a plurality of the rollers are respectively provided with a synchronous wheel, and the synchronous wheels are connected with a driving motor through a synchronous belt.

4. A fabric sheet weaving device according to claim 1 wherein the first roller set is located above the second roller set, and the fabric sheet passes around the first roller set from one side and then passes around the second roller set from the same side.

5. The fiber cloth weaving device of claim 1, wherein the vent hole on the upper surface of the bottom plate is provided with a floatable stopper, the stopper comprises a disc-shaped baffle plate, a connecting rod and a cross-shaped bracket, two ends of the connecting rod are respectively connected with the baffle plate and the bracket, the baffle plate is positioned above the vent hole, the bracket is positioned below the vent hole, the connecting rod penetrates through the vent hole, and the diameter of the baffle plate and the width of the bracket are both larger than the diameter of the vent hole.

6. A fabric cloth weaving device according to claim 1 wherein the stop is made of a lightweight material.