CN115507635A - Anti ultraviolet non-woven fabrics production is with guipure antibacterial drying-machine of taking cloth mechanism - Google Patents

Abstract

The invention discloses a mesh belt antibacterial drying machine with a cloth mechanism for the production of anti-ultraviolet non-woven fabrics. One side of the transfer box is provided with an inclined feeding port, and a vibrator is installed outside the inclined feeding port. The interior of the transfer box is provided with a heating leveling roller mechanism, the outlet of the transfer box is connected with the inlet of the antibacterial drying box, and the top of the antibacterial drying box is equipped with an antibacterial drying mechanism, and the antibacterial Dehumidification mechanisms are arranged on both sides of the drying mechanism, and a transmission mesh belt mechanism is arranged inside the antibacterial drying box. The mesh belt antibacterial dryer with a cloth mechanism for the production of anti-ultraviolet non-woven fabrics, this device solves the problem that the existing mesh belt dryer needs a large number of driving devices, by combining the first conveying mesh belt, the second The three transmission mesh belts and the fifth transmission mesh belt driving wheel are connected through the first transmission chain, while the second transmission mesh belt and the fourth transmission mesh belt driving wheel are connected through the second transmission chain.

Description

A mesh belt antibacterial dryer with a cloth mechanism for the production of anti-ultraviolet non-woven fabrics

technical field

The invention relates to the technical field of mesh belt antibacterial dryers, in particular to a mesh belt antibacterial dryer with a cloth mechanism for the production of anti-ultraviolet non-woven fabrics.

Background technique

Non-woven fabrics have the characteristics of breathability, mildew resistance, and durability, and their manufacturing speed is fast and the price is low. They are commonly used textiles in today's society. Non-woven fabrics are often used in a series of ranges such as carpets and curtains. For cloth art, it needs to have anti-ultraviolet function, so the market demand for anti-ultraviolet non-woven fabrics is gradually increasing. Mesh belt dryers are commonly used in the drying process of anti-ultraviolet non-woven fabrics. Mesh belt dryers are mainly The principle is to spread the cloth on the mesh belt, and the transmission device drags it to move back and forth in the dryer. The hot air flows through the materials, and the water vapor is discharged from the moisture discharge holes, so as to achieve the purpose of drying.

After a massive search, it was found that the prior art such as publication number CN202220335231.8 is a mesh belt dryer with a swinging cloth mechanism, which includes a main body of the dryer, and the mesh belt dryer also includes a cloth device. The cloth device includes a support, Geared motor, adjusting shaft, cloth barrel, rotating shaft, rotating connecting plate and eccentric wheel, the rotating shaft is vertically arranged and connected to the support in rotation, the rotating connecting plate is arranged horizontally and is located under the cloth barrel, and one end of the rotating connecting plate is solidly sleeved on the The rotating shaft and the other end are fixedly connected to the cloth tube. The geared motor is fixedly arranged on the support and is located on one side of the rotating shaft. The two ends are respectively rotatably connected to the circumference of the eccentric wheel and the end of the rotatably connecting plate away from the rotating shaft. The purpose of the utility model is to solve or at least alleviate the problem of failure or material drop when the scraper is used to flatten the material of the mesh belt dryer, and to provide a mesh belt dryer with a swinging material distribution mechanism.

The above-mentioned mesh belt dryer is equipped with a material distribution device at the feed inlet of the box body. The upper end of the cloth cylinder of the material distribution device is connected to the material conveying pipeline by rotation, and the lower end extends into the feed inlet of the box body. The rotating shaft is installed in the box body, and the geared motor drives the distribution cylinder to rotate reciprocally through the linkage mechanism. Cooperating with the translational conveying of the mesh belt, the material is covered with the mesh belt, and the material is spread on the mesh belt from the source without failure. Or falling from the mesh belt, but the above mesh belt dryer needs to use a large number of driving devices in the mesh belt conveying system during the cloth conveying process, resulting in an increase in mechanical costs. At the same time, the above mesh belt dryer may Wrinkles will appear, resulting in the inability to fully dry the wrinkled position of the fabric in the later stage. Therefore, a mesh belt antibacterial dryer with a fabric mechanism for the production of anti-ultraviolet non-woven fabrics is proposed to solve the above problems.

Contents of the invention

The object of the present invention is to provide a mesh belt antibacterial dryer with a cloth mechanism for the production of anti-ultraviolet non-woven fabrics, to solve the problem that the existing mesh belt dryer proposed in the above-mentioned background technology needs to use a large number of driving devices and Wrinkles may occur during shipping.

In order to achieve the above object, the present invention provides the following technical solutions: a mesh belt antibacterial dryer with a fabric mechanism for the production of UV-resistant non-woven fabrics, including a transfer box, one side of the transfer box is provided with an inclined feeding port, And a vibrator is installed on the outside of the inclined feeding port, a height adjustment mechanism is provided at the bottom of the transfer box, and the inside of the transfer box is connected with the transmission mechanism through a support rod, and a heating leveling roller mechanism is arranged inside the transfer box. The discharge port of the transfer box is connected with the feed port of the antibacterial drying box, and an antibacterial drying mechanism is installed on the top of the antibacterial drying box. Dehumidification mechanisms are arranged on both sides of the antibacterial drying mechanism, and the antibacterial drying mechanism The inside of the dry box is provided with a transmission mesh belt mechanism, and one side of the antibacterial drying box is connected with a box door through a hinge, and an observation port is opened on the box door.

Preferably, the height adjustment mechanism includes a fixed plate, and a hydraulic rod is arranged above the fixed plate, and the other end of the hydraulic rod is connected to the bottom of the transfer box through the mounting plate.

By adopting the above technical solution, it is convenient to adjust the height of the transfer box.

Preferably, the heating leveling roller mechanism includes a heating leveling roller, and connecting rods are connected to both sides of the heating leveling roller, the top of the connecting rod is connected to the inner top of the transfer box, and one side of the connecting rod is installed inside A micro motor, the output end of the micro motor is connected with the heating leveling roller.

By adopting the above technical solution, it is convenient to install and rotate the heating leveling roller in the later stage.

Preferably, the heating leveling roller includes a heat conduction layer, and a heating layer is provided inside the heat conduction layer, an electric heating tube is installed inside the heating layer, and the inside of the heating layer is connected to the inner core through reinforcing rods.

By adopting the above technical scheme, it is convenient to heat and shape the cloth while leveling.

Preferably, the antibacterial drying mechanism includes a protective cover, and the outer top of the protective cover is connected to the inner top of the antibacterial drying box, a cooling fan is installed on the inner top of the protective cover, and an electric heating wire is arranged under the cooling fan , a hollow plate is installed at the opening of the protective cover.

By adopting the above technical scheme, it is convenient to dry and sterilize the cloth.

Preferably, the dehumidification mechanism includes an air intake uniform disk, and the air intake uniform disk is located at the bottom of the inside of the antibacterial drying box, and the air intake uniform disk is connected to the fan outside the antibacterial drying box through an air intake pipe , and the other end of the fan is detachably connected to the S-type dehumidification pipe through the flow pipe. The outlet air distribution disc is connected.

By adopting the above technical scheme, it is convenient to remove the water vapor inside the antibacterial drying box.

Preferably, the S-shaped dehumidification pipe includes a pipe body, the outside of the pipe body is provided with an insulation layer, and the inside of the pipe body is covered with a layer of dehumidification layer.

By adopting the above technical scheme, it is convenient to adsorb water vapor.

Preferably, the conveying mesh belt mechanism includes a first conveying mesh belt, a second conveying mesh belt, a third conveying mesh belt, a fourth conveying mesh belt and a fifth conveying mesh belt from top to bottom, and the first conveying mesh belt The belt, the second conveying mesh belt, the third conveying mesh belt, the fourth conveying mesh belt and the fifth conveying mesh belt are all composed of driving wheels, and the driving wheel is connected with the driven wheel through the conveying mesh belt, and the driving wheel and the driven wheel One end is rotatably connected with the inner wall of the antibacterial drying box.

By adopting the above technical scheme, the transmission of cloth is facilitated.

Preferably, the first conveying mesh belt, the third conveying mesh belt, and the fifth conveying mesh belt driving wheel are connected through a first transmission chain, and the second conveying mesh belt and the fourth conveying mesh belt driving wheel pass through The second transmission chain is connected, one end of the driving wheel of the first transmission network belt is connected with the output end of the first driving motor, one end of the driving wheel of the second transmission network belt is connected with the output end of the second driving motor, and the fifth transmission The mesh belt is located on the side of the discharge port opened on the antibacterial drying box.

By adopting the above technical solution, it is convenient to reduce the number of driving motors used.

Compared with the prior art, the beneficial effect of the present invention is: the mesh belt antibacterial dryer with cloth mechanism for the production of anti-ultraviolet non-woven fabrics,

(1) In order to solve the problem that the existing mesh belt dryer needs a large number of driving devices, this device passes the first transmission mesh belt, the third transmission mesh belt, and the fifth transmission mesh belt driving wheel through the first transmission The chains are connected, and the second transmission mesh belt and the fourth transmission mesh belt drive wheel are connected through the second transmission chain. When in use, the first drive motor drives the first transmission network and the driving roller in the first transmission network to rotate. Under the action of the first transmission chain, the third conveyor belt and the fifth conveyor belt rotate synchronously to drive the conveyor belt to move. Similarly, the second drive motor drives the second conveyor network and the driving roller in the second conveyor network to move Rotate, under the action of the second transmission chain, the fourth conveyor belt rotates synchronously to drive the conveyor belt to move. This method can also be used when more conveyor belts are needed.

(2) In order to solve the problem that the existing mesh belt dryer is prone to wrinkles during the cloth transportation process, a vibrator is installed outside the inclined feeding port, and a heating leveling roller mechanism is installed inside the transfer box , put the cloth from the inclined feeding port into the inside of the transfer box, the setting of the vibrator can speed up the speed of the cloth sliding down from the inclined feeding port, and at the same time avoid the formation of wrinkles during the inclined shaking process, when the cloth is under the action of the transmission mechanism Move to the bottom of the heating leveling roller. At this time, the heating leveling roller moves synchronously with the transmission mechanism under the action of the micro motor, and the cloth above the transmission mechanism is leveled. At the same time, the heat emitted by the heating rod inside the heating leveling roller passes through The heat-conducting layer acts on the surface of the cloth to heat and shape the cloth to a certain extent.

(3) In order to solve the problem that the internal moisture of the existing mesh belt dryer cannot be absorbed in time, resulting in poor drying effect, this device installs an air inlet and an outlet air evening disk inside the antibacterial drying box , and the air inlet uniform disk is connected to the fan through the inlet pipe, the other end of the fan is connected to the S-type dehumidification pipe through the flow pipe, and the other end of the S-type dehumidification pipe is connected to the outlet air distribution disk through the double-headed air outlet pipe. When absorbing the water vapor inside the antibacterial drying box, turn on the fan, and under the action of the fan, the gas inside the antibacterial drying box enters the inside of the S-shaped dehumidification pipe through the intake pipe and the flow pipe, and is covered by the inside of the S-shaped dehumidification pipe. The dehumidification layer in the air absorbs the moisture in the gas, and after the adsorption, it enters the antibacterial drying box through the double-ended air outlet pipe and then the air outlet uniform air disc.

(4) In order to solve the problem of inconvenient maintenance of the internal equipment of the existing mesh belt dryer, this device is connected with a door on one side of the antibacterial drying box, and there is an observation port on the door, which can be passed through in daily conditions. Observe the internal conditions of the antibacterial drying box through the observation port. When the internal equipment of the antibacterial drying box needs maintenance, the door can be opened to maintain the internal equipment.

Description of drawings

Fig. 1 is the schematic diagram of the front view sectional structure of the present invention;

Fig. 2 is a schematic diagram of the front view section structure of the transfer box of the present invention;

Fig. 3 is the schematic diagram of the front view section structure of the bacteriostatic drying box of the present invention;

Fig. 4 is the structure schematic diagram of antibacterial drying oven of the present invention;

Fig. 5 is a side view structural schematic diagram of the bacteriostatic drying box of the present invention;

Fig. 6 is a structural schematic diagram of the heating leveling roller mechanism of the present invention;

Fig. 7 is a structural schematic diagram of the heating leveling roller of the present invention;

Fig. 8 is a structural schematic diagram of the antibacterial drying mechanism of the present invention;

Fig. 9 is a schematic structural diagram of the S-type dehumidification pipe of the present invention;

Fig. 10 is a structural schematic diagram of the positional relationship between the pipe body, the insulation layer and the dehumidification layer according to the present invention.

In the figure: 1. Transfer box; 2. Inclined feed inlet; 3. Vibrator; 4. Support rod; 5. Transmission mechanism; 6. Heating leveling roller mechanism; 7. Antibacterial drying box; 8. Box door ;9, observation port; 10, fixed plate; 11, hydraulic rod; 12, heating leveling roller; 13, connecting rod; 14, micro motor; 15, heat conduction layer; 16, heating layer; Inner core; 19. Protective cover; 20. Cooling fan; 21. Electric heating wire; 22. Hollow plate; 23. Air intake uniform disk; 24. Fan; 25. Flow pipe; 26. S-shaped dehumidification pipe; 27. Double-headed air outlet pipe; 28, air outlet uniform wind disc; 29, pipe body; 30, insulation layer; 31, dehumidification layer; 32, first conveyor belt; 33, second conveyor belt; 34, third conveyor belt ; 35, the fourth conveyor belt; 36, the fifth conveyor belt; 37, the first transmission chain; 38, the second transmission chain; 39, the discharge port.

detailed description

The following will clearly and completely describe the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some, not all, embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

Please refer to Figures 1-10, the present invention provides a technical solution: a mesh belt antibacterial dryer with a fabric mechanism for the production of UV-resistant non-woven fabrics. According to Figures 1-2 and 6-7, the transmission One side of the box 1 is provided with an inclined feed port 2, and a vibrator 3 is installed on the outside of the inclined feed port 2, and a height adjustment mechanism is provided at the bottom of the transfer box 1, and the inside of the transfer box 1 is connected with the transmission mechanism 5 through the support rod 4 , The inside of the transfer box 1 is provided with a heated leveling roller mechanism 6 .

In a further embodiment, the transmission mechanism 5 includes a driving wheel, and a motor is connected to one end of the driving wheel, the driving wheel is connected to the driven wheel through a transmission belt, and the driving wheel and the driven wheel are rotatably connected to the support rod 4 .

Specifically, the height adjustment mechanism includes a fixed plate 10, and a hydraulic rod 11 is arranged above the fixed plate 10, and the other end of the hydraulic rod 11 is connected to the bottom of the transfer box 1 through the mounting plate.

When the height of the transfer box 1 needs to be adjusted, the height of the transfer box 1 can be adjusted by opening the hydraulic lever 11 .

Specifically, the heated leveling roller mechanism includes a heating leveling roller 12, and connecting rods 13 are connected to both sides of the heating leveling roller 12 for rotation, and the top of the connecting rod 13 is connected to the inner top of the transfer box 1, and the inside of the connecting rod 13 on one side A micro motor 14 is installed, and the output end of the micro motor 14 is connected with the heating leveling roller 12 .

Specifically, the heating leveling roller 12 includes a heat conduction layer 15, and a heating layer 16 is arranged inside the heat conduction layer 15, and an electric heating tube is installed inside the heating layer 16, and the inside of the heating layer 16 is connected to the inner core 18 through a reinforcing rod (17 .

In still a further embodiment, the setting of the reinforcing rod 17 can reduce the influence of the heat generated by the electric heating tube in the heating layer on the inner core 18 , thereby prolonging the service life of the inner core 18 .

When in use, the cloth is put into the interior of the transfer box 1 from the inclined feeding port 2, and the setting of the vibrator 3 can accelerate the speed at which the cloth slides from the inclined feeding port 2, and at the same time, the formation of cloth wrinkles can be avoided during the inclined shaking process. The cloth moves to the bottom of the heating leveling roller 12 under the action of the transmission mechanism 5. At this time, the heating leveling roller 12 moves synchronously with the transmission mechanism 5 under the action of the micro motor 14, and the cloth above the transmission mechanism 5 is leveled. At the same time, the heat dissipated by the heating rod inside the heating leveling roller 12 acts on the surface of the cloth through the heat conducting layer 15, thereby heating and shaping the cloth to a certain extent.

According to Fig. 1, Fig. 3 and Fig. 8, the discharge port of the transfer box 1 is connected with the feed port of the antibacterial drying box 7, and the top of the antibacterial drying box 7 is equipped with an antibacterial drying mechanism.

Specifically, the antibacterial drying mechanism includes a protective cover 19, and the top of the outer side of the protective cover 19 is connected with the top of the inner side of the antibacterial drying box 7. The heating wire 21 is equipped with a hollow plate 22 at the opening of the protective cover 19 .

During use, the cloth enters the top of the transmission mesh belt mechanism inside the antibacterial drying box 7 after being leveled from the inside of the transmission box under the effect of the transmission mechanism 5. At this time, the cooling fan 20 and the electric heating wire 21 are opened, and the cooling fan 20 Under the action of the electric heating wire 21, the heat generated by the electric heating wire 21 is blown to the inside of the antibacterial drying box 7 through the hollow plate 22, so that the cloth is dried during the moving process of the conveying mesh belt mechanism.

According to Fig. 1, Fig. 3, Fig. 4-5 and Fig. 9-10, dehumidification mechanisms are arranged on both sides of the antibacterial drying mechanism, and a transmission mesh belt mechanism is arranged inside the antibacterial drying box 7 .

Concretely, the dehumidification mechanism includes an air intake uniform disk 23, and the air intake uniform disk 23 is located at the inside bottom of the antibacterial drying box 7, and the air intake uniform disk 23 passes through the air intake pipe and the fan 24 on the outside of the antibacterial drying box 7 The other end of the fan 24 is detachably connected to the S-type dehumidification pipe 26 through the flow pipe 25, and the other end of the S-type dehumidification pipe 26 is detachably connected to a double-ended air outlet pipe 27, and the double-ended air outlet pipe 27 is connected to the antibacterial drying The outlet air uniformity disks 28 arranged symmetrically on both sides of the mechanism are connected.

In a further embodiment, the S-shaped dehumidification pipe 26 includes a pipe body 29 , the outer side of the pipe body 29 is provided with an insulating layer 30 , and the inner side of the pipe body 29 is covered with a layer of dehumidification layer 31 .

In a further embodiment, an insulating layer is provided on the outside of the air intake pipe, the flow pipe 25 and the double-ended air outlet pipe 27 .

When the water vapor inside the antibacterial drying box 7 needs to be absorbed, the fan 24 is turned on, and the gas inside the antibacterial drying box 7 enters the inside of the S-shaped dehumidification pipe 26 through the air intake pipe and the flow pipe 25 under the action of the fan 24, The dehumidification layer 31 covered by the S-shaped dehumidification pipe 26 absorbs the moisture in the gas, and after the adsorption, it enters the antibacterial drying box 7 through the double-ended air outlet pipe 27 and then through the air outlet uniform disk 28 .

Concretely, the conveying mesh belt mechanism includes a first conveying mesh belt 32, a second conveying mesh belt 33, a third conveying mesh belt 34, a fourth conveying mesh belt 35 and a fifth conveying mesh belt 36 from top to bottom. A conveying net belt 32, the second conveying net belt 33, the 3rd conveying net belt 34, the 4th conveying net belt 35 and the 5th conveying net belt 36 are all by driving wheel, and driving wheel is connected with driven wheel by conveying net belt One end of the driving wheel and the driven wheel is rotationally connected with the 7 inner walls of the antibacterial drying box.

Concretely, the first transmission network belt 32, the third transmission network belt 34, and the fifth transmission network belt 36 driving wheels are connected through the first transmission chain 37, and the second transmission network belt 33 and the fourth transmission network belt 35 drive The wheels are connected by the second drive chain 38, one end of the first transmission mesh belt 32 driving wheels is connected with the output end of the first drive motor, one end of the second transmission mesh belt 33 driving wheels is connected with the output end of the second drive motor, and the fifth Conveyor mesh belt 36 is positioned at the discharge port 39 side that offers on antibacterial drying box 7.

During use, the first driving motor drives the first transmission net 32 and the driving roller in the first transmission net 32 to rotate, and the third transmission net belt 34 and the fifth transmission net 36 rotate synchronously under the action of the first transmission chain 37 , drive the conveying mesh belt to move, similarly the second driving motor drives the second conveying mesh 33 and the driving roller in the second conveying mesh 33 to rotate, and the fourth conveying mesh belt 35 is synchronized under the action of the second transmission chain 38 Rotate to drive the conveying mesh belt to move. When the cloth enters the antibacterial drying box 7, the cloth passes through the top of the first conveying mesh 32, the top of the second conveying mesh 33, the top of the third conveying mesh belt 34, and the fourth conveying mesh belt. 35 and above the fifth conveying net 36, and finally move from above the fifth conveying net 36 to the discharge port 39.

As shown in FIG. 4 , one side of the bacteriostatic drying box 7 is hingedly connected with a box door 8 , and an observation port 9 is provided on the box door 8 .

In a further embodiment, a door 8 is connected to one side of the antibacterial drying box 7, and an observation port 9 is provided on the door 8, and the internal conditions of the antibacterial drying box 7 can be observed through the observation port 9 in the daily state. , when the antibacterial drying box 7 internal equipment needs to be maintained, the chamber door 8 can be opened to maintain its internal equipment.

The terms "center", "portrait", "landscape", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", The orientation or positional relationship indicated by "outside" is based on the orientation or positional relationship shown in the drawings, and is only a simplified description for the convenience of describing the present invention, rather than indicating or implying that the referred device or element must have a specific orientation , are constructed and operated in a specific orientation, and thus cannot be construed as limiting the protection content of the present invention.

Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art can still modify the technical solutions described in the aforementioned embodiments, or perform equivalent replacements for some of the technical features. Within the spirit and principles of the present invention, any modifications, equivalent replacements, improvements, etc., shall be included in the protection scope of the present invention.

Claims (9)

1. A mesh belt antibacterial dryer with a cloth mechanism for the production of anti-ultraviolet nonwoven fabrics, comprising a transfer box (1), characterized in that: one side of the transfer box (1) is provided with an inclined feed port ( 2), and a vibrator (3) is installed on the outside of the inclined feeding port (2), the bottom of the transfer box (1) is provided with a height adjustment mechanism, and the inside of the transfer box (1) passes through the support rod (4) and the transmission mechanism (5) are connected, the inside of the transfer box (1) is provided with a heating leveling roller mechanism (6), and the discharge port of the transfer box (1) is connected with the feed port of the antibacterial drying box (7), And antibacterial drying box (7) top is equipped with antibacterial drying mechanism, described antibacterial drying mechanism both sides are provided with dehumidification mechanism, and antibacterial drying box (7) interior is provided with conveying mesh belt mechanism, so One side of the antibacterial drying box (7) is hingedly connected with a box door (8), and an observation port (9) is provided on the box door (8). 2. a kind of anti-ultraviolet non-woven fabric production according to claim 1 is characterized in that: described height adjustment mechanism comprises fixed plate (10), and fixed plate ( 10) A hydraulic rod (11) is arranged above, and the other end of the hydraulic rod (11) is connected to the bottom of the transfer box (1) through a mounting plate. 3. a kind of anti-ultraviolet non-woven fabric production according to claim 1 is characterized in that: described heating leveling roller mechanism comprises heating leveling roller (12), And the two sides of heating leveling roller (12) are connected with connecting rod (13) rotatingly, and the top of described connecting rod (13) is connected with the inner top of transfer box (1), and a miniature A motor (14), the output end of the micro motor (14) is connected with the heating leveling roller (12). 4. a kind of anti-ultraviolet non-woven fabric production according to claim 3 is characterized in that: described heating leveling roller (12) comprises heat-conducting layer (15), And the inside of the heat conduction layer (15) is provided with a heating layer (16), the inside of the heating layer (16) is equipped with an electric heating tube, and the inside of the heating layer (16) is connected to the inner core (18) through a reinforcing rod (17) . 5. The mesh belt bacteriostatic dryer with cloth mechanism for the production of a kind of anti-ultraviolet nonwoven fabric according to claim 1, characterized in that: the bacteriostatic drying mechanism includes a protective cover (19), and the protective Cover (19) outer top is connected with bacteriostasis drying box (7) inner top, and described protective cover (19) inner top is equipped with cooling fan (20), and the cooling fan (20) below is provided with electric heating wire ( 21), a hollow plate (22) is installed at the opening of the protective cover (19). 6. a kind of anti-ultraviolet non-woven fabric production according to claim 1 is characterized in that: described dehumidification mechanism comprises air-intake air-distributing disk (23), and carries out The air uniformity disk (23) is positioned at the inside bottom of the antibacterial drying box (7), and the air intake uniformity disk (23) is connected with the blower fan (24) on the outside of the antibacterial drying box (7) through the air inlet pipe, And the other end of the blower fan (24) is detachably connected with the S-type dehumidification pipe (26) through the flow pipe (25), and the other end of the S-type dehumidification pipe (26) is detachably connected with a double-ended air outlet pipe (27), and the double-ended The air outlet pipe (27) of the head is connected with the air outlet uniform air disc (28) symmetrically arranged on both sides of the antibacterial drying mechanism. 7. The mesh belt bacteriostatic dryer with cloth mechanism for the production of anti-ultraviolet non-woven fabrics according to claim 6, characterized in that: the S-shaped dehumidification pipe (26) comprises a pipe body (29), The outside of the pipe body (29) is provided with a thermal insulation layer (30), and the inside of the pipe body (29) is covered with a layer of dehumidification layer (31). 8. A mesh belt antibacterial dryer with a fabric mechanism for the production of UV-resistant non-woven fabrics according to claim 1, characterized in that: the conveyor mesh belt mechanism sequentially includes a first conveyor net from top to bottom belt (32), the second conveyor belt (33), the third conveyor belt (34), the fourth conveyor belt (35) and the fifth conveyor belt (36), and the first conveyor belt (32) , the second conveying mesh belt (33), the 3rd conveying mesh belt (34), the 4th conveying mesh belt (35) and the 5th conveying mesh belt (36) are all by driving wheel, and driving wheel passes through conveying mesh belt and from The driving wheel is connected, and one end of the driving wheel and the driven wheel is rotatably connected with the inner wall of the antibacterial drying box (7). 9. A mesh belt antibacterial dryer with a cloth mechanism for the production of UV-resistant nonwoven fabrics according to claim 8, characterized in that: the first conveyor belt (32), the third conveyor belt (34), and the fifth conveyor belt (36) driving wheel is connected by the first drive chain (37), and the second conveyor belt (33) and the fourth conveyor belt (35) driving wheel are passed through the first transmission chain Two drive chains (38) are connected, one end of the driving wheel of the first transmission mesh belt (32) is connected with the output end of the first driving motor, and one end of the driving wheel of the second transmission mesh belt (33) is connected with the output end of the second driving motor. In connection with each other, the fifth conveyor belt (36) is located on the side of the discharge port (39) provided on the antibacterial drying box (7).

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