CN117531639A - Manufacturing equipment and manufacturing process of graphene antibacterial health-care fabric - Google Patents

Abstract

The invention relates to the technical field of fabric spinning, and discloses a graphene antibacterial health-care fabric manufacturing device and a manufacturing process thereof, wherein the manufacturing device comprises a mounting bottom plate, a graphene rotating cavity is arranged on the mounting bottom plate through a supporting rod, the lower half part of the graphene rotating cavity is arranged in a spraying groove, and a baking and gluing component is arranged on one side of the spraying groove, which is used for discharging fabric; the manufacturing process comprises the steps of controlling the rocker to coat the protective adhesive layer on the fabric, controlling the feeding speed of graphene and the moving speed of the fabric so as to control the thickness of the fabric coated with the graphene.

Description

Manufacturing equipment and manufacturing process of graphene antibacterial health-care fabric

Technical Field

The invention relates to the technical field of fabric spinning, in particular to graphene antibacterial health-care fabric manufacturing equipment and a manufacturing process thereof.

Background

As a functional fabric, an antibacterial fabric has gradually come into the life of people and has been widely used. The existing antibacterial fabric is various in types, such as a traditional kapok fiber fabric, a chitosan fiber fabric, a fibrilia fabric and the like, and various unique effects of the antibacterial fabric are gradually applied to different fields along with the development of graphene materials in recent years, and the graphene antibacterial fabric is a novel fabric prepared by applying the antibacterial capability of graphene. Graphene fabrics are generally prepared by two methods, namely, a slice raw material and graphene are melt-blended in a spinning stage, and fibers containing graphene are prepared and then woven into the fabrics; and secondly, finishing the fabric by a padding method after the fabric is woven and molded, so that a layer of graphene is bonded on the surface of the fabric. Compared with the first method, the method through padding finishing has the advantages of simpler operation process, easy control of the graphene content, no agglomeration of the graphene caused by mixing and melting, and the like, and is a method more beneficial to large-scale industrial production.

Chinese patent CN113862926a discloses an antibacterial fabric based on graphene and a production process thereof, which specifically comprises: the shell is provided with feed inlets at two sides, and a guide device is arranged at the bottom of the inner wall of the shell; the extrusion roller sets are arranged at the part, above the guide device, inside the shell, and the extrusion roller sets are provided with two groups and are symmetrically distributed inside the shell; the stoving case, this stoving case setting is at the shell top, the direction opening has all been seted up to stoving case top and bottom, direction opening inner wall rotates and is connected with the polymerization compression roller, this antibacterial fabric based on graphite alkene and production technology thereof, sets up coating device inside stoving case, conveniently saves device occupation space to the convenience is with the inside air discharge of cloth, makes the contact of cloth and antibacterial agent solution more abundant, improves the antibacterial ability of cloth.

In the prior art, when the fabric is prepared, uniformity of graphene on the fabric cannot be guaranteed to be consistent, content of graphene on the fabric cannot be guaranteed, graphene oxide solution is generally adopted for soaking during padding arrangement, so that the solution for soaking adhesion on the fabric can fall off, and the fabric is easily scratched and falls off by a rotating shaft during transmission of the rotating shaft.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the invention provides the graphene antibacterial health-care fabric manufacturing equipment and the manufacturing process thereof, which are provided with the functions of uniformly smearing graphene, can ensure that the graphene is not scratched and falls off in the fabric manufacturing process, and solve the problems that the graphene fabric is smeared unevenly and falls off easily in the fabric manufacturing process.

(II) technical scheme

In order to achieve the aim of uniformly smearing the graphene and ensuring that the graphene is not scratched and falls off in the fabric manufacturing process, the invention provides the following technical scheme: the utility model provides a graphene antibacterial health care surface fabric manufacture equipment, includes mounting plate, be provided with the rotatory chamber of graphite alkene on the mounting plate through the bracing piece, rotatory chamber lower half sets up in the spraying inslot of graphite alkene, rotatory chamber up end of graphite alkene is provided with circumferencial direction's graphite alkene supply port, rotatory chamber lower terminal surface of graphite alkene is provided with graphite alkene spraying port, rotatory intracavity of graphite alkene is provided with the heating inner chamber, is located be provided with the baffle on the heating inner chamber of graphite alkene spraying port upper end position, graphite alkene supply equipment links to each other with graphite alkene supply port with graphite alkene is followed the wall of rotatory chamber of graphite alkene is spouted, the rotatory chamber both sides of graphite alkene are provided with the surface fabric support, follow after the surface fabric that waits to process after passing through the surface fabric support the spraying groove with pass between the rotatory chamber lower terminal surface of graphite alkene, one side of spraying groove discharge surface fabric is provided with toasts the rubber coating subassembly.

Preferably, the baking and gluing assembly comprises a supporting plate, the center of the supporting plate is provided with a baking module, the baking module comprises a baking cavity, the baking cavity is connected with an absorber through an air suction pipeline, lifting slide rods are arranged on the supporting plate at the left side and the right side of the baking cavity, limiting springs are sleeved on the lifting slide rods, the upper ends of the baking cavity are connected with semi-cylindrical heating surfaces, the upper ends of the baking module are provided with gluing modules, the gluing modules comprise gluing covers sleeved at the upper ends of the semi-cylindrical heating surfaces, the left end surface and the right end surface of each gluing cover are provided with round limiting blocks, the centers of the round limiting blocks are provided with connecting rods, the lower ends of the connecting rods are connected with connecting plates, the connecting plates are connected with the lifting slide rods, the limiting springs are arranged between supporting bottom plates and the centers of the connecting plates are connected with height adjusting bolts arranged on the supporting bottom plates through holes.

Preferably, the fabric support comprises a mounting rod, and a fabric rotating shaft is arranged on the mounting rod.

Preferably, the semicircular side edges of the spraying groove are outwards extended with circular guard plates.

Preferably, the lower end of the spraying groove is connected with the immersion liquid cavity, the immersion liquid cavity is internally provided with wetting liquid, the immersion liquid cavity is arranged in the lifting groove, the inner side surface of the bottom of the lifting groove is provided with a buffer spring, the buffer spring is connected with the bottom of the immersion liquid cavity, and the lower end surface of the lifting groove is connected with the fixing rod.

Preferably, the inner side of the gluing cover is a semicircular surface, the radius of the semicircular surface is equal to that of the semi-cylindrical heating surface, and the semicircular surface is provided with an adsorption through hole.

Preferably, a semicircular balance needle is arranged on the inner surface of the circular limiting block, and a glue pulling rod is arranged between the semicircular balance needles.

Preferably, the left side and the right side of the gluing cover are provided with glue stick arc supporting plates.

Preferably, a semicircular balance pin arranged on the circular limiting block is connected with a rocker on the outer end face of the circular limiting block.

The manufacturing process of the graphene antibacterial health-care fabric is characterized by comprising the following steps of:

step one: firstly, the spraying groove is pressed manually, so that the buffer spring is compressed and then drives the spraying groove to descend, and a gap between the inner wall of the spraying groove and the graphene rotating cavity is enlarged;

step two: the method comprises the steps that a fabric to be coated with graphene passes through the upper end of a fabric rotating shaft, passes through a gap between a graphene rotating cavity and a spraying groove, passes through the gap, passes through the lower end of the fabric rotating shaft at the left end, and enters a baking and gluing assembly;

step three: lifting the gluing cover by adjusting the height adjusting bolt before the fabric enters the baking gluing assembly, and adjusting the height adjusting bolt again after penetrating the fabric, so that the thickness between the semicircular surface distance fabrics on the inner side of the gluing cover is equal to the diameter of the glue pulling rod;

step four: opening the baking cavity to heat the semi-cylindrical heating surface, dragging the fabric through the recovery winding drum to move, introducing graphite into the graphene rotating cavity while moving the fabric, enabling the graphite to be soaked and adhered with the graphene to enter the gluing baking cavity, rocking the rocker, smearing the adhesive layer on the surface of the fabric sprayed with the graphene, and simultaneously enabling the adhesive layer to be quickly melted by the semi-cylindrical heating surface to be adhered to the fabric, so that manufacturing is completed.

(III) beneficial effects

Compared with the prior art, the invention provides the graphene antibacterial health-care fabric manufacturing equipment and the manufacturing process thereof, and the graphene antibacterial health-care fabric manufacturing equipment has the following beneficial effects:

1. according to the graphene antibacterial health-care fabric manufacturing equipment, the graphene rotating cavity and the spraying groove are arranged, so that the graphene can be fully mixed and dispersed in the rotating cavity, and the spraying effect is ensured. The equipment structure is simple, the operation is convenient, the uniform spraying of graphene on the fabric can be realized, and the production efficiency is improved. The graphene feeding equipment is connected with the graphene feeding port, so that continuous feeding of graphene can be realized, and the stability of the production process is ensured. The setting of baking glue spreading subassembly can further strengthen the cohesion of graphite alkene and surface fabric, improve the antibacterial health care performance of surface fabric, can change the thickness of graphite alkene spraying on the surface fabric at any time through the rolling speed of control surface fabric, make the graphite alkene spraying thickness of beating on the same piece surface fabric realize the coating of different thickness according to the thickness requirement in different regions, when the surface fabric lays graphite alkene through the swirl chamber, because the two-dimensional lamellar structure of graphite alkene itself, and graphite alkene is through the swirl air current wrap up in the surface fabric surface of blowing in the removal process, like this when graphite alkene granule falls on the surface fabric, receive the wind after, can natural tiling to the surface fabric, like this can make graphite alkene with great lamellar direct tiling on the surface fabric surface, like this under the coating state of being thinner, can be bigger keep the coating characteristic of graphite alkene, through the graphite alkene that the air current wraps up in the state of holding the rotation groove between graphite alkene rotation chamber and heating inner chamber in the spraying, the graphite alkene heating inner chamber heats up, make it can be better to infiltrate and be adhered to the surface fabric, can further reduce the mutual even graphene deposition probability of graphite alkene that can be stacked down in a large scale, the surface fabric is realized, the surface fabric is sprayed down, can be greatly reduced simultaneously, the surface fabric is stacked down.

2. This antibacterial health care surface fabric manufacture equipment of graphite alkene is through the setting of baking the rubber coating subassembly for the surface fabric can be quick carry out the glue film protection after spraying graphite alkene and attach, simultaneously can the quick dehydration, and the adsorption effect through semi-cylindrical heating up face makes the graphite alkene with the surface fabric attached inseparabler when rising the temperature and melting the glue film, and the intracavity links to each other with the adsorber through the pipeline of breathing in, can guarantee that the in-process that the surface fabric coated the glue film keeps fixed position not taking place the skew, makes the coating face more even.

3. According to the manufacturing process of the graphene antibacterial health-care fabric, the buffer spring is compressed by manually pressing the spraying groove, so that the spraying groove is lowered, gaps between the inner wall of the spraying groove and the graphene rotating cavity are enlarged, and the fabric can smoothly pass through. And enabling the fabric to be coated with graphene to pass through the upper end of the fabric rotating shaft, and then pass through a gap between the graphene rotating cavity and the spraying groove, and then pass through the lower end of the fabric rotating shaft at the left end to enter the baking and gluing assembly after passing through the gap. The even distribution of graphene on the fabric is guaranteed, the glue coating cover is lifted by adjusting the height adjusting bolts before the fabric enters the baking glue coating assembly, and after the fabric is penetrated, the height adjusting bolts are adjusted again, so that the thickness between semicircular surface distance fabrics on the inner side of the glue coating cover is equal to the diameter of the glue pulling rod. Ensure the even smearing of the glue layer. Opening the baking cavity to heat the semi-cylindrical heating surface, dragging the fabric through the recovery winding drum to move, introducing graphite into the graphene rotating cavity while moving the fabric, enabling the graphite to enter the gluing baking cavity after being soaked, shaking the rocker, smearing the adhesive layer on the surface of the fabric sprayed with the graphene, and enabling the adhesive layer to be adhered to the fabric by quickly melting the semi-cylindrical heating surface. The tight combination of the graphene and the fabric is realized, and the antibacterial health-care performance of the fabric is improved.

Drawings

Fig. 1 is a schematic diagram of a three-dimensional structure of graphene antibacterial healthcare fabric manufacturing equipment in the invention;

fig. 2 is a schematic diagram of a perspective structure of a graphene rotating cavity of graphene antibacterial healthcare fabric manufacturing equipment in the invention;

fig. 3 is a schematic diagram of a perspective structure of an ejection groove of graphene antibacterial healthcare fabric manufacturing equipment in the invention;

fig. 4 is a sectional view of a graphene rotating cavity of the graphene antibacterial healthcare fabric manufacturing equipment in the invention;

fig. 5 is a schematic perspective view of a baking and gluing assembly of graphene antibacterial healthcare fabric manufacturing equipment in the invention;

fig. 6 is a schematic diagram of a three-dimensional structure of a baking cavity and a semi-cylindrical heating surface of graphene antibacterial health-care fabric manufacturing equipment;

fig. 7 is a schematic diagram of a three-dimensional structure of a gluing cover of graphene antibacterial healthcare fabric manufacturing equipment;

fig. 8 is a front view of a graphene antibacterial healthcare fabric manufacturing device in the invention.

In the figure: the device comprises a 1-mounting bottom plate, a 2-supporting rod, a 3-spraying groove, a 4-graphene rotating cavity, a 5-fabric support, a 6-baking and gluing component, 7-fabrics, a 31-circular guard plate, a 32-immersion cavity, a 33-lifting groove, 34-buffer springs, 35-fixing rods, 41-graphene supply ports, 42-graphene spraying ports, 43-heating inner cavities, 44-baffle plates, 51-fabric rotating shafts, 52-mounting rods, 61-supporting plates, 62-baking modules, 63-gluing modules, 621-semi-cylindrical heating surfaces, 622-baking cavities, 623-lifting sliding rods, 624-limiting springs, 625-height adjusting bolts, 631-gluing covers, 632-glue rod arc supporting plates, 633-circular limiting blocks, 634-semicircular swinging needles, 635-glue poking rods, 636-rocking rods, 637-connecting rods and 638-connecting plates.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-3, a graphene antibacterial healthcare fabric manufacturing device comprises a mounting base plate 1, a graphene rotating cavity 4 is arranged on the mounting base plate 1 through a supporting rod 2, the lower half part of the graphene rotating cavity 4 is arranged in a spraying groove 3, a graphene supply port 41 in the circumferential direction is arranged on the upper end face of the graphene rotating cavity 4, a graphene spraying port 42 is arranged on the lower end face of the graphene rotating cavity 4, a heating inner cavity 43 is arranged in the graphene rotating cavity 4, a baffle 44 is arranged on the heating inner cavity 43 at the upper end position of the graphene spraying port 42, graphene is sprayed into the graphene rotating cavity 4 along the wall surface of the graphene supply port 41 by the graphene supply device, fabric supports 5 are arranged on two sides of the graphene rotating cavity 4, a fabric 7 to be processed passes through the space between the spraying groove 3 and the lower end face of the graphene rotating cavity 4 after passing through the fabric supports 5, and a baking and gluing component 6 is arranged on one side of the fabric 7 discharged by the spraying groove 3.

The graphene feeding equipment is connected with the graphene feeding port 41, and the graphene is sprayed along the wall surface of the graphene rotating cavity 4. And fabric brackets 5 are arranged on two sides of the graphene rotating cavity 4. The fabric 7 to be processed passes through the space between the spraying groove 3 and the lower end surface of the graphene rotating cavity 4 after passing through the fabric support 5. One side of the spraying groove 3, which discharges the fabric 7, is provided with a baking and gluing component 6. The buffer spring 34 is compressed by manually pressing the spraying groove 3, so that the spraying groove 3 descends, a gap between the inner wall of the spraying groove 3 and the graphene rotating cavity 4 is enlarged, and the fabric 7 can smoothly pass through.

The fabric 7 to be coated with graphene passes through the upper end of the fabric rotating shaft 51, passes through a gap between the graphene rotating cavity 4 and the spraying groove 3, passes through the gap, passes through the lower end of the fabric rotating shaft 51 at the left end, and enters the baking and gluing assembly 6. Before the fabric 7 enters the baking and gluing assembly 6, the gluing cover 631 is lifted by adjusting the height adjusting bolt 625, and after penetrating the fabric 7 again, the height adjusting bolt 625 is adjusted again, so that the thickness between the semicircular surfaces on the inner side of the gluing cover 631 and the fabric 7 is equal to the diameter of the glue pulling rod 635. Opening the baking cavity 622 to heat the semi-cylindrical heating surface 621, dragging the fabric 7 to move through the recovery winding drum, introducing graphite into the graphene rotating cavity 4 while the fabric 7 moves, adhering the graphene after being soaked, entering the gluing baking cavity 622, shaking the rocker 636, smearing the adhesive layer on the surface of the fabric 7 sprayed with the graphene, and simultaneously enabling the adhesive layer to be quickly melted by the semi-cylindrical heating surface 621 to adhere the adhesive layer to the fabric 7, so that the manufacturing is completed.

The fabric support 5 comprises a mounting rod 52, and a fabric rotating shaft 51 is arranged on the mounting rod 52. The mounting rod 52 is used as a supporting structure, so that stability and reliability of the fabric rotating shaft 51 can be ensured, and shaking or deflection in the manufacturing process can be avoided. The arrangement of the fabric rotating shaft 51 enables the fabric 7 to be kept flat in the rotating process, avoids wrinkling or twisting of the fabric 7, and improves manufacturing precision and quality. Through the cooperation of the mounting rod 52 and the fabric rotating shaft 51, the position and the angle of the fabric 7 can be conveniently adjusted, so that the processing of the fabric 7 is more flexible and efficient.

The semicircular side edges of the spraying groove 3 are outwards extended with circular guard plates 31. The spraying groove 3 lower extreme links to each other with the immersion liquid chamber 32, the immersion liquid is stored in the immersion liquid chamber 32, the immersion liquid chamber 32 sets up in the lift groove 33, lift groove 33 bottom medial surface be provided with buffer spring 34 with the immersion liquid chamber 32 bottom links to each other, lift groove 33 lower terminal surface links to each other with dead lever 35.

The semicircular side edges of the spraying groove 3 are outwards extended with the circular guard plates 31, so that the fabric 7 can be prevented from being scratched in the spraying process, meanwhile, the equipment can be protected from external interference, and the stability and the service life of the equipment are improved. The lower end of the spraying groove 3 is connected with the immersion liquid cavity 32, and the immersion liquid cavity 32 stores wetting liquid. The design ensures that the graphene can be better adhered to the fabric 7 under the action of wetting liquid, and improves the antibacterial health-care performance of the fabric 7. The immersion liquid cavity 32 is arranged in the lifting groove 33, and a buffer spring 34 is arranged on the inner side surface of the bottom of the lifting groove 33, and the buffer spring 34 is connected with the bottom of the immersion liquid cavity 32. This design allows the immersion chamber 32 to be lifted and lowered as needed to accommodate different thickness fabrics 7, while the presence of the buffer spring 34 can absorb vibrations and shocks, improving the stability and lifetime of the device. The lower end surface of the lifting groove 33 is connected with the fixing rod 35, so that the whole equipment is more stable, can bear larger load and pressure, and improves the reliability and durability of the equipment.

The inner side of the gluing cover 631 is a semicircular surface, and the radius of the semicircular surface is equal to that of the semi-cylindrical heating surface 621. Glue stick circular arc supporting plates 632 are arranged on the left side and the right side of the glue coating cover 631.

The glue spreading link of the manufacturing equipment of the graphene antibacterial healthcare fabric 7 is further optimized through the semicircular surface, and the uniformity and stability of glue spreading are improved. The inner side of the gluing cover 631 is a semicircle surface, and the radius of the semicircle surface is equal to that of the semi-cylindrical heating surface 621. This design allows glue cover 631 to be tightly attached to semi-cylindrical heated surface 621, ensuring glue uniformity and stability. Glue spreading cover 631 is provided with glue stick circular arc support plates 632 on the left and right sides. The design enables the glue sticks to be evenly distributed under the support of the arc support plate, so that shaking and falling of the glue sticks are avoided, and the glue spreading efficiency and quality are improved.

A semicircular swing needle 634 is arranged on the inner surface of the circular limiting block 633, and a glue pulling rod 635 is arranged between the semicircular swing needles 634. The semicircular balance needle 634 arranged on the circular limiting block 633 is connected with the rocker 636 on the outer end surface of the circular limiting block 633.

The semicircular balance needle 634 is matched with the glue pulling rod 635 to coat the surface of the fabric 7, so that the glue coating effect and the operation convenience of the graphene antibacterial health-care fabric 7 manufacturing equipment are further enhanced. A semicircular swing needle 634 is arranged on the inner surface of the circular limiting block 633, and a glue pulling rod 635 is arranged between the semicircular swing needles 634. The design makes the glue pulling rod 635 capable of achieving accurate and uniform glue coating through the guiding function of the semicircular balance needle 634, improves glue coating efficiency and uniformity, and the semicircular balance needle 634 arranged on the circular limiting block 633 is connected with the rocker 636 on the outer end face of the circular limiting block 633. This design allows an operator to shake the rocker 636 to move the semicircular balance needle 634 and the glue pulling rod 635, thereby automating and facilitating the gluing process.

Referring to fig. 4, a graphene rotating cavity 4 is disposed on the mounting base plate 1 through a support rod 2, the lower half of the graphene rotating cavity 4 is disposed in a spraying groove 3, the upper end surface of the graphene rotating cavity 4 is provided with a graphene supply port 41 in the circumferential direction, the lower end surface of the graphene rotating cavity 4 is provided with a graphene spraying port 42, a heating cavity 43 is disposed in the graphene rotating cavity 4, which can heat and dry graphene, prevent adhesion between graphene, a baffle 44 is disposed on the heating cavity 43 at the upper end position of the graphene spraying port 42, graphene supply equipment is connected with the graphene supply port 41 to spray graphene along the wall surface of the graphene rotating cavity 4, wherein the inner wall of the heating cavity 43 and the inner wall of the graphene rotating cavity 4 form a graphene rotating groove, the arrow direction in the rotating groove is the rotation direction of graphene, the graphene is continuously blown into the graphene rotating cavity 4 through the airflow, so that the graphene always keeps a moving state in the spraying process, the graphene in the moving state is blown onto the fabric 7 relatively to the graphene in the static state by pressing down directly, the graphene cannot be stacked together to cause uneven thickness, the graphene is paved more uniformly, the thickness is more consistent, the arrow direction outside the graphene rotating cavity 4 is the moving direction of the fabric 7, the longer the time of the fabric passing through the graphene spraying opening 42 is, the more sprayed graphene is, the thicker the graphene is paved on the fabric 7, therefore, the spraying thickness of the graphene can be controlled by controlling the winding speed of the fabric 7, the thickness of the graphene airflow passing through the graphene spraying opening 42 can be controlled by controlling the turnover angle of the baffle 44, and when the thickness is smaller, the higher the aggregation degree of the graphene is, the more the graphene is sprayed from the graphene spraying opening, so that the thickness of a graphene layer sprayed on the fabric 7 by the graphene can be controlled by controlling the overturning angle of the baffle 44, and the graphene layer and the baffle are matched, so that the more accurate adjustment of the graphene spraying thickness is realized.

Referring to fig. 5-8, the baking and gluing assembly 6 includes a support plate 61, a baking module 62 is disposed at the center of the support plate 61, the baking module 62 includes a baking cavity 622, lifting slide bars 623 are disposed on the support plate 61 at the left and right sides of the baking cavity 622, a limit spring 624 is sleeved on the lifting slide bars 623, the upper end of the baking cavity 622 is connected with a semi-cylindrical heating surface 621, a gluing module 63 is disposed at the upper end of the baking module 62, the gluing module 63 includes a gluing cover 631 sleeved at the upper end of the semi-cylindrical heating surface 621, round stoppers 633 are disposed at the left and right end surfaces of the gluing cover 631, a connecting rod 637 is disposed at the center of the round stoppers 633, the lower end of the connecting rod 637 is connected with a connecting plate 638, the connecting plate is connected with the lifting slide bars 623, the limit spring 624 is disposed between the supporting base plate and the connecting plate 638, and the center of the connecting plate 638 is connected with a height adjusting bolt 625 disposed on the supporting base plate through a through hole.

Placing the object to be glued below the gluing cover 631, ensuring that the object is aligned with the gluing cover 631, starting the gluing module 63, enabling the gluing cover 631 to ascend and contact with the object, enabling the limiting spring 624 to be compressed through the cooperation of the connecting rod 637 and the connecting plate 638 in the ascending process of the gluing cover 631, enabling the gluing cover 631 to be tightly attached to the object after the gluing cover 631 contacts with the object, starting a gluing operation, controlling the rocker 636 to conduct semicircular reciprocating motion on the inner wall of the gluing cover 631, and smearing the protective glue layer on the surface of the fabric 7 after spraying the graphene. After the glue is applied, the glue cover 631 is closed to make it closely adhere to the object. The bake module 62 is activated to bake the object to cure the glue or paint. After baking is completed, the baking chamber 622 door is opened and the baked object is taken out. Through control system, can realize automatic rubber coating and toast the operation, improve production efficiency. Through accurate gluing and baking control, consistency and stability of product quality can be ensured. The gluing and baking operations can be completed through simple operation steps, and manual intervention is reduced.

The combination of the baking module 62 and the gluing module 63 realizes the high efficiency of manufacturing the graphene antibacterial healthcare fabric 7. The baking module 62 can heat the semi-cylindrical heating surface 621 to quickly cure the protective adhesive layer coated on the fabric 7, and the gluing module 63 can uniformly smear the adhesive layer on the fabric 7 through the gluing cover 631. The design of the lifting slide bar 623 and the limiting spring 624 ensures that the gluing cover 631 can be kept stable in the baking process, and avoids the position deviation caused by thermal expansion and cold contraction. Meanwhile, the limiting spring 624 can absorb vibration and impact, so that the stability and the service life of the device are improved. The design of circular stopper 633 and connecting rod 637 makes glue coating cover 631 closely fit on semi-cylindrical heating surface 621, has ensured the homogeneity and the stability of rubber coating. Meanwhile, the connecting rod 637 can be connected with the lifting slide rod 623 through the connecting plate 638, so that automation and convenience of the gluing process are realized. The height adjusting bolt 625 is arranged to enable an operator to adjust the height of the gluing cover 631 according to actual needs, so that the fabric 7 with different thicknesses can be adapted. Meanwhile, the design of the through holes enables the connecting plate 638 to be connected with the supporting base plate through the height adjusting bolts 625, so that flexibility and adjustability of the device are improved.

In the manufacturing process, the fabric 7 to be processed passes through the space between the spraying groove 3 and the lower end surface of the graphene rotary cavity 4 through the fabric support 5. In the spraying groove 3, graphene adheres to the surface of the soaked fabric 7, and then enters a gluing baking assembly. During the gluing process, the gluing cover 631 is tightly attached to the semi-cylindrical heating surface 621 by the guiding action of the circular limiting block 633 and the connecting rod 637. Meanwhile, the lifting slide bar 623 and the limiting spring 624 are kept stable under the action of the lifting slide bar 623 and the limiting spring 624, and in the baking process, the semi-cylindrical heating surface 621 is heated to quickly solidify the protective adhesive layer on the fabric 7, and the protective adhesive layer is combined with the fabric 7 to form the antibacterial health-care fabric 7. After the baking and gluing process is completed, an operator can adjust the height of the gluing cover 631 through the height adjusting bolt 625, so as to adapt to the fabrics 7 with different thicknesses. Meanwhile, the swinging rocker 636 drives the semicircular swinging needle 634 and the glue pulling rod 635 to move, so that automation and convenience of a gluing process are realized.

The manufacturing process of the graphene antibacterial health-care fabric is characterized by comprising the following steps of:

step one: manually pressing the spraying groove 3 to enable the spraying groove 3 to descend after the buffer spring 34 is compressed, so that a gap between the inner wall of the spraying groove 3 and the graphene rotating cavity 4 is enlarged;

the position of the spraying groove 3 can be controlled rapidly and accurately by manual pressing, so that a complex mechanical transmission and control system is avoided, and the operation difficulty is reduced. Through the mode of manual pressing, can conveniently wash spraying groove 3 and maintain, prolonged the life of equipment. The mode of manual pressing has avoided the risk of mechanical failure and unexpected injury, has improved the security of production.

Step two: the fabric 7 to be coated with graphene passes through the upper end of the fabric rotating shaft 51, passes through a gap between the graphene rotating cavity 4 and the spraying groove 3, passes through the gap, passes through the lower end of the fabric rotating shaft 51 at the left end, and enters the baking and gluing assembly 6;

by accurately controlling the transfer path of the fabric 7, the operation time and the labor cost can be reduced, the production efficiency is improved, the deformation and damage of the fabric 7 in the transfer process are reduced, and the product quality is ensured. Through simple operation steps, the transfer and subsequent gluing and baking operations of the fabric 7 can be completed, the manual intervention is reduced, and the operation and maintenance are convenient.

Step three: before the fabric 7 enters the baking and gluing assembly 6, the gluing cover 631 is lifted by adjusting the height adjusting bolt 625, and after penetrating the fabric 7, the height adjusting bolt 625 is adjusted again, so that the thickness between the semicircular surfaces on the inner side of the gluing cover 631 and the fabric 7 is equal to the diameter of the glue pulling rod 635;

by precisely controlling the distance and the position between the gluing cover 631 and the fabric 7, the uniformity and the thickness of gluing can be ensured, the gluing quality can be improved, the waste of gluing materials can be reduced, and the production cost can be reduced. Through simple operation steps, the adjustment of the gluing cover 631 and subsequent gluing operation can be completed, manual intervention is reduced, and the operation and maintenance are convenient.

Step four: opening a baking cavity 622 to heat a semi-cylindrical heating surface 621, dragging a fabric 7 to move through a recovery reel, introducing graphite into a graphene rotating cavity 4 while the fabric 7 moves, soaking the graphite, adhering the graphene to enter the gluing baking cavity 622, shaking a rocker 636, smearing a glue layer on the surface of the fabric 7 sprayed with the graphene, and simultaneously, rapidly melting the glue layer by the semi-cylindrical heating surface 621 to adhere the glue layer to the fabric 7 to finish manufacturing;

through automatic and continuous operation, the working procedures of spraying graphene, smearing and drying the adhesive layer and the like can be rapidly completed, and the production efficiency is improved. By precisely controlling the temperature of the baking cavity 622, the temperature of the semi-cylindrical heating surface 621, and the amount of graphite and the adhesive layer, uniform distribution and firm adhesion of the graphene and the adhesive layer on the fabric 7 can be ensured, and the product quality is improved. The device can adapt to the surface fabric 7 of different specifications and types, through adjustment parameter and change part, can realize the graphite alkene spraying and the rubber coating demand of multiple surface fabric 7.

The method has the advantages that the graphene sprayed on the fabric 7 is guaranteed to be uniform enough, the speed of pulling out and winding the fabric 7 through the winding drum determines the spraying uniformity of the graphene on the fabric 7, meanwhile, the graphene is in a laminar shape, when the graphene particles fall onto the fabric 7, the graphene particles are blown by wind and naturally and then spread onto the fabric 7, the graphene can be directly spread on the surface of the fabric 7 in a larger laminar shape, the coating characteristic of the graphene can be reserved greatly in a thinner coating state, in the process of passing the fabric 7 through the spraying groove 3, the penetrating fluid in the immersion cavity 32 wets the passing fabric 7, the graphene sprayed out through the graphene spraying opening 42 can be adhered to the surface of the fabric 7 better, the graphene moves along the inner wall of the graphene rotating cavity 4 after passing through the graphene supplying opening 41, so that the graphene is diffused and rotated in the graphene rotating cavity 4, a part of the periphery of the graphene fluid is sprayed onto the surface of the fabric 7 through the graphene opening 42 at the lower end, the fabric 7 is sprayed out of the fabric 7, the fabric 6 is controlled to enter the rocker arm, the fabric 7 is sprayed out, and the fabric is sprayed on the surface of the fabric 7, and the fabric is sprayed and baked, and the fabric 7 is sprayed on the fabric 7, and the fabric is quickly heated, and the fabric is sprayed and baked; in the baking and gluing assembly 6, the height of the gluing module 63 can be changed by controlling the height adjusting bolt 625, so that the thickness of the glue coating layer can be changed according to the thickness of the fabric 7, and the gluing requirements of different fabrics 7 can be met. The graphene is wrapped and clamped by the air flow and continuously blown into the graphene rotating cavity 4, the graphene always keeps in a moving state in the spraying process, the graphene in the moving state is blown onto the fabric 7 relatively and directly in a downward pressing static state, the graphene is not stacked on the fabric, the thickness is uneven, the graphene is paved more uniformly, the thickness is more consistent, the arrow direction outside the graphene rotating cavity 4 is the moving direction of the fabric 7, the longer the time of the fabric passing through the graphene spraying opening 42 is, the more sprayed graphene is, the thicker the graphene is paved on the fabric 7, the thickness of the sprayed graphene can be controlled by controlling the winding speed of the fabric 7, the thickness of the graphene can be controlled by controlling the turnover angle of the baffle 44, the higher the aggregation degree of the graphene is, the more the graphene sprayed from the graphene spraying opening is indicated, the thickness of the graphene layer can be controlled by controlling the turnover angle of the baffle 44, and the thickness of the graphene layer sprayed on the fabric 7 is matched with the graphene layer by controlling the turnover angle of the baffle 44, so that the accurate adjustment of the thickness of the graphene is realized.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a graphene antibacterial health care surface fabric manufacture equipment, includes mounting plate (1), its characterized in that: the utility model discloses a spray coating device, including mounting plate (1), graphite alkene rotating chamber (4) is provided with on mounting plate (1) through bracing piece (2), graphite alkene rotating chamber (4) lower half sets up in spraying groove (3), graphite alkene rotating chamber (4) up end is provided with circumferencial direction's graphite alkene feed port (41), graphite alkene rotating chamber (4) lower terminal surface is provided with graphite alkene spraying port (42), be provided with heating inner chamber (43) in graphite alkene rotating chamber (4), be located be provided with baffle (44) on heating inner chamber (43) of graphite alkene spraying port (42) upper end position, graphite alkene feed equipment links to each other with graphite alkene feed port (41) and spouts graphite alkene along the wall of graphite alkene rotating chamber (4), graphite alkene rotating chamber (4) both sides are provided with surface fabric support (5), wait to process surface fabric (7) pass through behind surface fabric support (5) spray coating groove (3) with graphite alkene rotating chamber (4) down the terminal surface is passed through between the terminal surface, gets into one side of spraying groove (3) discharge surface fabric (7) sets up stoving subassembly (6).

2. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 1 is characterized in that: toast rubber coating subassembly (6) including backup pad (61), backup pad (61) center is provided with toasts module (62), toast module (62) including toasting chamber (622), toast and link to each other with the adsorber through the pipeline of breathing in chamber (622), be provided with lift slide bar (623) on backup pad (61) of toasting chamber (622) left and right sides, the cover is equipped with spacing spring (624) on lift slide bar (623), toast chamber (622) upper end and semi-cylindrical heating surface (621) link to each other, toast module (62) upper end and be provided with rubber coating module (63), rubber coating module (63) are including the cover to be established glue coating cover (631) upper end, glue coating cover (631) left and right sides terminal surface is provided with circular stopper (633), circular stopper (633) center is provided with connecting rod (637), connecting rod (637) lower tip and connecting plate (638) link to each other, connecting plate (638) with lift spring (624) set up support base plate (638) with link to each other with between the connecting plate (638) and connecting plate (638) are in through the setting up height of connecting plate (638) between the connecting plate and connecting plate (638) and the setting up through the height.

3. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 1 is characterized in that: the fabric support (5) comprises a mounting rod (52), and a fabric rotating shaft (51) is arranged on the mounting rod (52).

4. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 1 is characterized in that: the semicircular side edges of the spraying grooves (3) are outwards extended to form circular guard plates (31).

5. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 1 is characterized in that: the spraying groove (3) lower extreme links to each other with immersion liquid chamber (32), the wetting fluid has been stored in immersion liquid chamber (32), immersion liquid chamber (32) set up in lift groove (33), lift groove (33) bottom medial surface is provided with buffer spring (34), buffer spring (34) with immersion liquid chamber (32) bottom links to each other, terminal surface and dead lever (35) link to each other under lift groove (33).

6. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 2, wherein: the inner side of the gluing cover (631) is a semicircular surface, the radius of the semicircular surface is equal to that of the semi-cylindrical heating surface (621), and an adsorption through hole is formed in the semicircular surface.

7. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 2, wherein: a semicircular swing needle (634) is arranged on the inner surface of the circular limiting block (633), and a glue pulling rod (635) is arranged between the semicircular swing needles (634).

8. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 2, wherein: the left side and the right side of the gluing cover (631) are provided with a rubber rod circular arc supporting plate (632).

9. The graphene antibacterial healthcare fabric manufacturing equipment according to claim 7 is characterized in that: a semicircular balance needle (634) arranged on the circular limiting block (633) is connected with a rocker (636) on the outer end face of the circular limiting block (633).

10. The manufacturing process of the graphene antibacterial health-care fabric is characterized by comprising the following steps of:

step one: firstly, the spraying groove (3) is pressed manually, so that the buffer spring (34) is compressed and then drives the spraying groove (3) to descend, and a gap between the inner wall of the spraying groove (3) and the graphene rotating cavity (4) is enlarged;

step two: the method comprises the steps that a fabric (7) to be coated with graphene passes through the upper end of a fabric rotating shaft (51), passes through a gap between a graphene rotating cavity (4) and a spraying groove (3), passes through the gap, passes through the lower end of the fabric rotating shaft (51) at the left end, and enters a baking and gluing assembly (6);

step three: before the fabric (7) enters the baking and gluing assembly (6), lifting the gluing cover (631) by adjusting the height adjusting bolt (625), and after penetrating the fabric (7), adjusting the height adjusting bolt (625) again to ensure that the thickness between the semicircular surfaces on the inner side of the gluing cover (631) and the fabric (7) is equal to the diameter of the glue pulling rod (635);

step four: opening the baking cavity (622) to heat the semi-cylindrical heating surface (621), dragging the fabric (7) to move through the recovery winding drum, introducing graphite into the graphene rotating cavity (4) while the fabric (7) moves, enabling the graphite to enter the gluing baking cavity (622) after being soaked, shaking the rocker (636), smearing the adhesive layer on the surface of the fabric (7) sprayed with the graphene, and enabling the adhesive layer to be quickly melted by the semi-cylindrical heating surface (621) to adhere to the fabric (7), so that manufacturing is completed.