CN115228812B

CN115228812B - Water-jet nonwoven integrated processing equipment and working method thereof

Info

Publication number: CN115228812B
Application number: CN202210851061.3A
Authority: CN
Inventors: 孙丙华; 蒋炀超青
Original assignee: Shantou Dingtaifeng Industrial Co ltd
Current assignee: Shantou Dingtaifeng Industrial Co ltd
Priority date: 2022-07-19
Filing date: 2022-07-19
Publication date: 2024-05-17
Anticipated expiration: 2042-07-19
Also published as: CN115228812A

Abstract

The invention discloses a spun-laced non-woven fabric integrated processing device and a working method thereof, and relates to the technical field of non-woven fabrics.

Description

Water-jet nonwoven integrated processing equipment and working method thereof

Technical Field

The invention relates to the technical field of non-woven fabrics, in particular to a spun-laced non-woven fabric integrated processing device and a working method thereof.

Background

The spun-laced non-woven fabric is one of non-woven fabrics, and various integrated processing equipment need be used in its structural process, for example, the patent of application number CN202110750589.7 discloses a spun-laced non-woven fabric processing is with disinfection integrated device that disinfects, including the casting part, the casting part includes upright baffle, well bearing roller, left roller, right roller, left linking arm, right linking arm and drive shaft. According to the invention, the casting part is arranged in the sterilizing and disinfecting box, the vertical partition plate is arranged on the casting part and divides the sterilizing and disinfecting box into the sterilizing and disinfecting cavity and the cleaning cavity, the middle carrier roller, the left roller and the right roller are arranged on the casting part, the middle carrier roller is positioned at the top of the vertical partition plate, the left roller is positioned in the sterilizing and disinfecting cavity, the right carrier roller is positioned in the cleaning cavity, and the spun-laced non-woven fabric is horizontally distributed and contacted with the middle carrier roller when in use, and the left roller and the right roller are respectively contacted with liquid in the sterilizing and disinfecting cavity and the cleaning cavity, so that the liquid can be cast by rotation of the left roller and the right roller, the cast liquid not only can wet the non-woven fabric, but also has the function of lifting the non-woven fabric, and further the occurrence of deformation of the spun-laced non-woven fabric can be avoided.

However, this integrated device of disinfection for water thorn non-woven fabrics processing also has some problems, for example, its disinfection is many directly uses fixed shower nozzle to go on, because the distribution scope of shower nozzle is limited, lead to antiseptic solution and water thorn non-woven fabrics contact's scope less, antiseptic solution is difficult to the complete water thorn non-woven fabrics that soaks in this less scope, influence disinfection effect, and during the washing, water thorn non-woven fabrics is many direct slides in the inside of wash water, utilize the activity of water thorn non-woven fabrics to wash, and wash water itself is difficult to frequently pass water thorn non-woven fabrics this just is difficult to take away the spot and the antiseptic solution of water thorn non-woven fabrics inside completely, influence disinfection effect.

Disclosure of Invention

The application aims to provide a spun-laced non-woven fabric integrated processing device and a working method thereof, which are used for solving the problems in the background technology.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a water thorn non-woven fabrics integration processing equipment, includes that non-woven fabrics handles case and the inside sliding connection's of non-woven fabrics handle the water thorn non-woven fabrics area, the inside middle-end welding of non-woven fabrics handles the case has the baffle, the inside left side rotation of non-woven fabrics handles the case is connected with the rolling wheel, the inside rotation of non-woven fabrics handles the case is connected with the rolling wheel, the winding has the driving rope between the inside of rolling wheel and the rolling wheel, the top bolt of driving rope has a mouth type to spout the board, the inside right side of non-woven fabrics handles the case articulates there is T type frame, the top of T type frame articulates there is the pin lever, the equal sliding connection of slide hole at T type frame both ends has the cock stem, the surface sliding connection of cock stem has a water squeezing tube, the left side bolt of non-woven fabrics handles the case has power unit, power unit's inside meshing has drive mechanism, rolling wheel and all bolt with drive mechanism, drive mechanism articulates.

By means of the structure, the range of spraying disinfectant by the mouth-shaped spray plate is increased by utilizing the left-right sliding of the mouth-shaped spray plate, the mouth-shaped spray plate can spray disinfectant to the spun-laced non-woven fabric belt in a larger range, the disinfectant can be soaked in a longer moving space, a disinfection effect is ensured, water flow can be driven to quickly move up and down through the movement of the plug rod in the water squeezing cylinder, water flow is enabled to quickly pass through the spun-laced non-woven fabric belt, flowing water flow is utilized to walk the stain disinfectant inside the spun-laced non-woven fabric belt, and the like, so that the spun-laced non-woven fabric belt is thoroughly cleaned.

Preferably, the power mechanism comprises a gear motor, a worm wheel, an eccentric wheel and a connecting ring, wherein the right side of the gear motor is in bolt connection with the left side of the non-woven fabric treatment box, the output end of the gear motor penetrates through a hole in the left side of the non-woven fabric treatment box and is in bolt connection with the left end of the worm, the right end of the surface of the worm is meshed with the bottom of the worm wheel, the axle center of the rear side of the worm wheel is in bolt connection with the right side of the axle center of the eccentric wheel, the outer side of the eccentric wheel is in rotary sleeve connection with the inner side of the connecting ring, and the power mechanism further comprises a connecting component hinged with the connecting ring.

Further, switch on gear motor's power, gear motor can drive the worm and rotate, the worm rotates the setting through bearing and non-woven fabrics processing case, let the worm can steadily rotate, avoid the worm to rock, the worm can drive the worm wheel and rotate, the worm wheel rotates the setting through bearing and non-woven fabrics processing case, let the worm wheel can steadily rotate, the worm wheel can drive the eccentric wheel and rotate, be eccentric structure between eccentric wheel and the worm wheel, the worm wheel drives eccentric wheel and rotates the in-process and drive the eccentric wheel and move down earlier then drive the eccentric wheel and upwards move, so reciprocating, the eccentric wheel can rotate and drive the upper and lower removal of connector ring in the inside of connector ring.

Preferably, the connecting assembly comprises a long rack, a connecting gear, a large chain wheel and a chain, wherein the bottom of the connecting ring is hinged to the top end of the long rack, teeth on the right side of the long rack are meshed with teeth on the left side of the connecting gear, the rear side of the connecting gear is bolted to the surface of the large chain wheel, the axle center of the large chain wheel is rotationally connected with the inside of the non-woven fabric treatment box, the teeth of the large chain wheel are meshed with the left side of the inside of the chain, and the chain is meshed with the transmission mechanism.

Further, when the connecting ring moves downwards, the connecting ring can drive the long rack to move downwards, the long rack can drive the connecting gear to rotate anticlockwise, the connecting gear can drive the large chain wheel to rotate anticlockwise, the large chain wheel is arranged through the bearing and the inside rotation of the non-woven fabric treatment box, the large chain wheel can rotate stably, the large chain wheel can drive the chain to rotate anticlockwise, and the chain can drive the transmission mechanism to rotate anticlockwise.

Preferably, the surface sliding connection of long rack has the stop collar, the rear side of stop collar and the inside bolt of non-woven fabrics processing case, be eccentric structure between worm wheel and the eccentric wheel, the axle center department of worm wheel runs through the hole of eccentric wheel rear side and is connected with the inside rotation of non-woven fabrics processing case.

Further, the long rack slides through the limiting sleeve to be limited, so that the long rack can stably move up and down, the long rack is prevented from deviating, an eccentric structure between the worm wheel and the eccentric wheel is avoided, the eccentric wheel can be driven to move up and down in the rotation process of the worm wheel, the worm wheel is arranged in a rotating mode through the bearing and the non-woven fabric treatment box, and the worm wheel can stably rotate.

Preferably, the transmission mechanism comprises a small sprocket, a T-shaped rack, a pinion and a small fluted disc, wherein the right side of the inside of the chain is meshed with teeth of the small sprocket, the axle center of the small sprocket is rotationally connected with the inside of the non-woven fabric treatment box, a lug on the surface of the small sprocket is slidably connected with a sliding hole of the T-shaped rack, the bottom end of the T-shaped rack is hinged with the inside of the non-woven fabric treatment box, the left side of the middle end of the top of the T-shaped rack is meshed with teeth of the bottom of the pinion, the rear side of the pinion is bolted with the surface of a winding wheel, the right side of the middle end of the top of the T-shaped rack is meshed with the bottom of the small fluted disc, and the rear side of the small fluted disc is bolted with the surface of the winding wheel.

Further, the chain can drive the small chain wheel to rotate, the small chain wheel is arranged through the bearing and the inner rotation of the non-woven fabric treatment box, the small chain wheel can rotate stably, the lug of the small chain wheel can slide in the sliding hole of the T-shaped rack in the rotation process of the small chain wheel and drive the T-shaped rack to move rightwards, then the T-shaped rack is driven to rotate leftwards, so that the T-shaped rack reciprocates, when the T-shaped rack rotates rightwards, the T-shaped rack can drive the pinion to rotate anticlockwise, the pinion can drive the winding wheel to rotate anticlockwise, the T-shaped rack can drive the small fluted disc to rotate anticlockwise, and the small fluted disc can drive the winding wheel to rotate anticlockwise.

Preferably, the drive assembly comprises a large conical gear, a small conical gear, a rotating rod, a main helical gear and a secondary helical gear, wherein the rear side of the small chain wheel is in bolt connection with the surface of the large conical gear, teeth on the right side of the large conical gear are meshed with teeth on the rear side of the small conical gear, the axle center of the right side of the small conical gear is in bolt connection with the left end of the rotating rod, the surface of the rotating rod is in rotary sleeve joint with a hole of the partition plate, the right end of the rotating rod extends to the right side of the inside of the non-woven fabric treatment box and is in bolt connection with the axle center of the left side of the main helical gear, teeth on the top of the main helical gear are meshed with teeth on the bottom of the secondary helical gear, and the axle center of the secondary helical gear is in rotary connection with the inside of the non-woven fabric treatment box, and the top of the surface of the secondary helical gear is hinged with the left end of the hinging rod.

Further, the small chain wheel can drive the large bevel gear to rotate, the large bevel gear can drive the small bevel gear to rotate, the small bevel gear can drive the rotary rod to rotate, the rotary rod can drive the main helical gear to rotate, the main helical gear and the auxiliary helical gear are helical gears, the main helical gear and the auxiliary helical gear can be meshed, the main helical gear is convenient to drive the auxiliary helical gear to rotate, the auxiliary helical gear is arranged through the bearing and the non-woven fabric treatment box to rotate, the auxiliary helical gear can rotate steadily, an eccentric structure is formed between the auxiliary helical gear and the hinging rod, and the hinging rod can be driven to move positively and negatively in the rotation process of the auxiliary helical gear.

Preferably, the T-shaped rack is composed of a sliding frame and an arc-shaped rack at the top of the sliding frame, a sliding hole of the sliding frame is in sliding connection with a lug on the surface of a small sprocket, the bottom of the small gear is meshed with the top of the arc-shaped rack, the bottom of the small fluted disc is meshed with the top of the arc-shaped rack, the small bevel gear is located at the rear side of the T-shaped rack, and the rotating rod is located at the rear side of the water squeezing barrel.

Further, the bull stick passes through the bearing and rotates the setting with the baffle, lets the bull stick can steadily rotate, and the structure of T type rack lets little sprocket can slide with the balladeur train and drive the balladeur train and rotate, and the balladeur train rotates the in-process and can drive arc rack and rotate, and arc rack can drive pinion and little fluted disc and rotate, and the structure of pinion and T type rack lets both can not mutual interference at the rotation in-process.

Preferably, the inside rotation of non-woven fabrics processing case is connected with guide roller group, the surface of water thorn non-woven fabrics area and the inside sliding connection of guide roller group, the inside both sides of driving rope all sliding connection has the pulley, the axle center department of pulley is rotated with the inside of non-woven fabrics processing case and is connected.

Further, the guide roller set can guide the spun-laced non-woven fabric belt, the spun-laced non-woven fabric belt is of a W-shaped structure, the spun-laced non-woven fabric belt is convenient to disinfect and clean, the two pulleys can effectively guide the transmission rope, the transmission rope is of a triangular structure, the top of the transmission rope is in a left-right horizontal state, and the transmission rope is convenient to drive the mouth-shaped spray plate to move.

Preferably, the water inlet has been seted up to the bottom of a water squeezing side, the top of water squeezing side and the inside bolt of non-woven fabrics processing box, the front side and the rear side at mouth shape spray board top all bolt have the sliding sleeve, the inside sliding connection of sliding sleeve has the stabilizer bar, the both ends of stabilizer bar all with the inside bolt of non-woven fabrics processing box, the top and the bottom of mouth shape spray board both sides all rotate and are connected with the rubber roller.

Further, in the downstream in-process of cock stem, utilize the water inlet to let water get into the water squeezing tube, conveniently change the inside water of water squeezing tube, the sliding sleeve can let the sliding sleeve slide on the stabilizer bar by the mouth shape spouts the board in-process, utilize the slip of stabilizer bar and sliding sleeve to carry out the slip spacing about to mouth shape spouting the board, let mouth shape spouts the board and can steady side-to-side movement, avoid mouth shape spouting the board and appear the skew, mouth shape spouts the board side-to-side movement in-process and can drive the rubber roller and remove, utilize the rubber roller can form cavity structure in the inside of mouth shape spouting the board, the rubber roller can extrude the water thorn non-woven fabrics area, let antiseptic solution can soak into the water thorn non-woven fabrics area.

The invention also provides a working method of the integrated processing equipment for the spun-laced non-woven fabric, which comprises the following steps:

S1: the mouth-shaped spray plate is communicated with a storage tank of disinfectant through a water pump, cleaning water is poured into a cavity at the right side of the inside of the non-woven fabric treatment tank, the spun-laced non-woven fabric belt penetrates through a guide roller set in the inside of the non-woven fabric treatment tank, and the spun-laced non-woven fabric belt penetrates through the inside of the mouth-shaped spray plate;

S2: the power mechanism can drive the winding wheel and the winding wheel to rotate through the transmission mechanism, the winding wheel and the winding wheel can drive the mouth-shaped spray plate to move through the transmission rope, the mouth-shaped spray plate can rapidly move left and right on the spun-laced non-woven fabric belt, and spray holes at the top and the bottom of the inner side of the mouth-shaped spray plate are used for spraying the spun-laced non-woven fabric belt to disinfect the spun-laced non-woven fabric belt;

S3: the transmission mechanism can drive the T-shaped frame to rotate through the hinging rod, and the T-shaped frame can drive water in the water squeezing cylinder to flow through the plug rod, so that the water can rapidly impact and clean the spun-laced non-woven fabric belt;

s4: the spun-laced non-woven fabric belt is pulled out for drying after being disinfected and cleaned.

In summary, the invention has the technical effects and advantages that:

1. The power mechanism can drive the winding wheel and the winding wheel to rotate through the transmission mechanism, the winding wheel and the winding wheel can drive the mouth-shaped spray plate to move through the transmission rope, the mouth-shaped spray plate can rapidly move left and right on the spun-laced non-woven fabric belt, and spray holes at the top and the bottom of the inner side of the mouth-shaped spray plate are used for spraying the spun-laced non-woven fabric belt to disinfect the spun-laced non-woven fabric belt;

2. the transmission mechanism can drive the T-shaped frame to rotate through the hinging rod, and the T-shaped frame can drive water in the water squeezing cylinder to flow through the plug rod, so that the water can rapidly impact and clean the spun-laced non-woven fabric belt;

Utilize the left and right sides of mouth shape to spout the board and increase mouth shape and spout the scope that the board sprayed the antiseptic solution, let mouth shape spout the board and can spray the antiseptic solution to the water thorn non-woven fabrics area in bigger scope, let the antiseptic solution can soak the antiseptic solution in longer travel space, ensure disinfection effect, moreover, can drive rivers through the inside removal of cock stem in the water squeezing tube and reciprocate fast, thereby let rivers pass the water thorn non-woven fabrics area fast, utilize the inside spot antiseptic solution of water thorn non-woven fabrics area of flowing water stream area walking etc. to carry out more thorough washing to the water thorn non-woven fabrics area.

Drawings

FIG. 1 is a schematic diagram of a front view of an embodiment of the present application;

FIG. 2 is a schematic diagram of a power mechanism according to an embodiment of the present application;

FIG. 3 is a schematic view of a partial structure of a transmission mechanism according to an embodiment of the present application;

FIG. 4 is a schematic diagram of a large sprocket according to an embodiment of the present application;

FIG. 5 is a schematic view of a rear view of a chain according to an embodiment of the present application;

FIG. 6 is a schematic diagram of a left-hand structure of a nozzle plate according to an embodiment of the present application;

FIG. 7 is a schematic perspective view of a take-up reel according to an embodiment of the present application;

Fig. 8 is a schematic perspective view of an eccentric wheel according to an embodiment of the present application.

In the figure: 1. a non-woven fabric treatment box; 2. a power mechanism; 21. a speed reducing motor; 22. a worm; 23. a worm wheel; 24. an eccentric wheel; 25. a connecting ring; 26. a long rack; 27. a connecting gear; 28. a large sprocket; 29. a chain; 3. a transmission mechanism; 31. a small sprocket; 32. a T-shaped rack; 33. a pinion gear; 34. a small fluted disc; 35. a large bevel gear; 36. a pinion bevel gear; 37. a rotating rod; 38. a main helical gear; 39. a secondary helical gear; 4. a spun-laced nonwoven belt; 5. a partition plate; 6. a guide roller group; 7. a winding wheel; 8. a rolling wheel; 9. a driving rope; 10. a pulley; 11. a mouth-shaped spray plate; 12. a hinge rod; 13. a T-shaped frame; 14. a plug rod; 15. a wringing cylinder; 16. a sliding sleeve; 17. a stabilizer bar; 18. rubber roller.

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.

Examples

Referring to fig. 1-8, in this embodiment, a spun-laced nonwoven fabric integrated processing device is provided, which comprises a nonwoven fabric processing box 1 and a spun-laced nonwoven fabric belt 4 slidingly connected inside the nonwoven fabric processing box 1, wherein a baffle 5 is welded at the middle end inside the nonwoven fabric processing box 1, a winding wheel 7 is rotationally connected at the left side inside the nonwoven fabric processing box 1, a driving rope 9 is wound between the winding wheel 7 and the winding wheel 8, one end of the driving rope 9, far away from the winding wheel 7, of the driving rope 9 is wound with the interior of the winding wheel 8, a mouth-shaped spray plate 11 is bolted to the top of the driving rope 9, a T-shaped frame 13 is hinged to the top of the T-shaped frame 13, plug rods 14 are slidingly connected to sliding holes at two ends of the T-shaped frame 13, a water squeezing drum 15 is slidingly connected to the surface of the plug rods 14, a power mechanism 2 is connected to the left side of the nonwoven fabric processing box 1, a driving mechanism 3 is meshed with the driving mechanism 3, and a driving mechanism 3 is meshed with the driving mechanism 3.

By means of the mechanism, the range of spraying disinfectant by the mouth-shaped spray plate 11 is increased by utilizing the left-right sliding of the mouth-shaped spray plate 11, the mouth-shaped spray plate 11 can spray disinfectant to the spun-laced non-woven fabric belt 4 in a larger range, the disinfectant can be soaked in a longer moving space, the disinfection effect is ensured, and water flow can be driven to quickly move up and down by moving the plug rod 14 in the water squeezing cylinder 15, so that the water flow can quickly pass through the spun-laced non-woven fabric belt 4, and the spun-laced non-woven fabric belt 4 is thoroughly cleaned by utilizing the flowing water flow to remove stains disinfectant and the like in the spun-laced non-woven fabric belt 4.

As a preferred embodiment of this embodiment, as shown in fig. 2, the power mechanism 2 includes a gear motor 21, a worm 22, a worm wheel 23, an eccentric wheel 24 and a connecting ring 25, the right side of the gear motor 21 is bolted to the left side of the non-woven fabric treatment box 1, the output end of the gear motor 21 penetrates through a hole on the left side of the non-woven fabric treatment box 1 and is bolted to the left end of the worm 22, the right end of the surface of the worm 22 is meshed with the bottom of the worm wheel 23, the axis of the rear side of the worm wheel 23 is bolted to the right side of the axis of the eccentric wheel 24, the outer side of the eccentric wheel 24 is rotatably sleeved in the connecting ring 25, and the power mechanism 2 further includes a connecting component hinged to the connecting ring 25.

The power of gear motor 21 is put through, gear motor 21 can drive worm 22 rotation, worm 22 rotates through bearing and non-woven fabrics processing case 1 to set up, let worm 22 can steadily rotate, avoid worm 22 to rock, worm 22 can drive worm wheel 23 and rotate, worm wheel 23 rotates through bearing and non-woven fabrics processing case 1 to set up, let worm wheel 23 can steadily rotate, worm wheel 23 can drive eccentric wheel 24 rotation, be eccentric structure between eccentric wheel 24 and the worm wheel 23, worm wheel 23 drives eccentric wheel 24 and rotates the in-process and drives eccentric wheel 24 and move down earlier then drive eccentric wheel 24 and upwards move, so reciprocating, eccentric wheel 24 can rotate and drive the tie-up ring 25 and reciprocate in the inside of tie-up ring 25, utilize eccentric structure can drive the structure transmission, guarantee structure transmission's smoothness.

In this embodiment, as shown in fig. 2, the connecting assembly includes a long rack 26, a connecting gear 27, a large sprocket 28 and a chain 29, the bottom of the connecting ring 25 is hinged to the top end of the long rack 26, teeth on the right side of the long rack 26 are meshed with teeth on the left side of the connecting gear 27, the rear side of the connecting gear 27 is bolted to the surface of the large sprocket 28, the axle center of the large sprocket 28 is rotationally connected with the inside of the non-woven fabric processing box 1, the teeth of the large sprocket 28 are meshed with the left side of the inside of the chain 29, and the chain 29 is meshed with the transmission mechanism 3.

When the connecting ring 25 moves downwards, the connecting ring 25 can drive the long rack 26 to move downwards, the long rack 26 can drive the connecting gear 27 to rotate anticlockwise, the connecting gear 27 can drive the large chain wheel 28 to rotate anticlockwise, the large chain wheel 28 is arranged in the non-woven fabric treatment box 1 in a rotating way through a bearing, the large chain wheel 28 can rotate stably, the large chain wheel 28 can drive the chain 29 to rotate anticlockwise, the chain 29 can drive the transmission mechanism 3 to rotate anticlockwise, and smooth structure transmission can be ensured by structure transmission.

In this embodiment, as shown in fig. 2, the surface of the long rack 26 is slidably connected with a stop collar, the rear side of the stop collar is bolted to the inside of the non-woven fabric treatment box 1, an eccentric structure is formed between the worm wheel 23 and the eccentric wheel 24, and the axis of the worm wheel 23 penetrates through a hole at the rear side of the eccentric wheel 24 and is rotationally connected with the inside of the non-woven fabric treatment box 1.

The long rack 26 slides through the limit sleeve to limit, so that the long rack 26 can stably move up and down, the long rack 26 is prevented from deviating, an eccentric structure between the worm wheel 23 and the eccentric wheel 24 is avoided, the eccentric wheel 24 can be driven to move up and down in the rotation process of the worm wheel 23, the worm wheel 23 is rotatably arranged with the non-woven fabric treatment box 1 through a bearing, and the worm wheel 23 can stably rotate.

In this embodiment, as shown in fig. 2, the transmission mechanism 3 includes a small sprocket 31, a T-shaped rack 32, a pinion 33 and a small toothed disc 34, the right side inside the chain 29 is engaged with the teeth of the small sprocket 31, the axle center of the small sprocket 31 is rotationally connected with the inside of the nonwoven fabric processing box 1, the bump on the surface of the small sprocket 31 is slidingly connected with the sliding hole of the T-shaped rack 32, the bottom end of the T-shaped rack 32 is hinged with the inside of the nonwoven fabric processing box 1, the left side of the middle end of the top of the T-shaped rack 32 is engaged with the teeth of the bottom of the pinion 33, the rear side of the pinion 33 is bolted with the surface of the winding wheel 7, the right side of the middle end of the top of the T-shaped rack 32 is engaged with the bottom of the small toothed disc 34, the rear side of the small toothed disc 34 is bolted with the surface of the winding wheel 8, and the transmission mechanism 3 further includes a driving component bolted with the small sprocket 31.

The chain 29 can drive the small chain wheel 31 to rotate, the small chain wheel 31 is rotatably arranged in the non-woven fabric treatment box 1 through a bearing, the small chain wheel 31 can rotate stably, a lug of the small chain wheel 31 can slide in a sliding hole of the T-shaped rack 32 in the rotation process of the small chain wheel 31 and drive the T-shaped rack 32 to move rightwards, then the T-shaped rack 32 is driven to rotate leftwards, in this way, when the T-shaped rack 32 rotates rightwards, the T-shaped rack 32 can drive the pinion 33 to rotate anticlockwise, the pinion 33 can drive the winding wheel 7 to rotate anticlockwise, the T-shaped rack 32 can drive the small fluted disc 34 to rotate anticlockwise, and the small fluted disc 34 can drive the winding wheel 8 to rotate anticlockwise, so that structural transmission can be driven.

In this embodiment, as shown in fig. 3, the driving assembly includes a large bevel gear 35, a small bevel gear 36, a rotating rod 37, a main bevel gear 38 and a secondary bevel gear 39, wherein the rear side of the small sprocket 31 is bolted to the surface of the large bevel gear 35, the teeth on the right side of the large bevel gear 35 are meshed with the teeth on the rear side of the small bevel gear 36, the axle center of the right side of the small bevel gear 36 is bolted to the left end of the rotating rod 37, the surface of the rotating rod 37 is rotatably sleeved with the hole of the partition 5, the right end of the rotating rod 37 extends to the right side inside the non-woven fabric processing box 1 and is bolted to the axle center of the left side of the main bevel gear 38, the teeth on the top of the main bevel gear 38 are meshed with the teeth on the bottom of the secondary bevel gear 39, the axle center of the secondary bevel gear 39 is rotatably connected with the inside of the non-woven fabric processing box 1, and the top of the surface of the secondary bevel gear 39 is hinged to the left end of the hinging rod 12.

The small chain wheel 31 can drive the large bevel gear 35 to rotate, the large bevel gear 35 can drive the small bevel gear 36 to rotate, the small bevel gear 36 can drive the rotating rod 37 to rotate, the rotating rod 37 can drive the main bevel gear 38 to rotate, the main bevel gear 38 and the auxiliary bevel gear 39 are bevel gears, the main bevel gear 38 and the auxiliary bevel gear 39 can be meshed, the main bevel gear 38 can conveniently drive the auxiliary bevel gear 39 to rotate, the auxiliary bevel gear 39 is rotatably arranged with the non-woven fabric treatment box 1 through a bearing, the auxiliary bevel gear 39 can stably rotate, an eccentric structure is formed between the auxiliary bevel gear 39 and the hinging rod 12, and the hinging rod 12 can be driven to positively and negatively move in the rotating process of the auxiliary bevel gear 39.

In this embodiment, as shown in fig. 2, the T-shaped rack 32 is composed of a carriage and an arc-shaped rack on the top of the carriage, a sliding hole of the carriage is slidably connected with a bump on the surface of the small sprocket 31, the bottom of the small gear 33 is meshed with the top of the arc-shaped rack, the bottom of the small gear disc 34 is meshed with the top of the arc-shaped rack, the small bevel gear 36 is located at the rear side of the T-shaped rack 32, and the rotating rod 37 is located at the rear side of the wringing barrel 15.

The bull stick 37 rotates the setting through bearing and baffle 5, lets bull stick 37 can steadily rotate, and the structure of T type rack 32 lets little sprocket 31 can slide and drive the balladeur train and rotate with the balladeur train, and the balladeur train rotates the in-process and can drive the arc rack and rotate, and the arc rack can drive pinion 33 and little fluted disc 34 and rotate, and the structure of pinion 36 and T type rack 32 lets both can not mutual interference at the rotation in-process.

In this embodiment, as shown in fig. 1, a guiding roller set 6 is rotatably connected to the inside of the nonwoven fabric treatment box 1, the surface of the spun-laced nonwoven fabric belt 4 is slidably connected to the inside of the guiding roller set 6, two sides of the inside of the driving rope 9 are slidably connected to pulleys 10, and the axle center of the pulleys 10 is rotatably connected to the inside of the nonwoven fabric treatment box 1.

The guide roller set 6 can guide the spun-laced non-woven fabric belt 4, so that the spun-laced non-woven fabric belt 4 is of a W-shaped structure, the spun-laced non-woven fabric belt 4 is convenient to disinfect and clean, the two pulleys 10 can effectively guide the driving rope 9, the driving rope 9 is of a triangular structure, the top of the driving rope 9 is in a left-right horizontal state, and the driving rope 9 is convenient to drive the mouth-shaped spray plate 11 to move.

In this embodiment, as shown in fig. 1, a water inlet is formed in the bottom of the side surface of the wringing barrel 15, the top of the rear side of the wringing barrel 15 is bolted to the inside of the non-woven fabric treatment box 1, the front side and the rear side of the top of the mouth-shaped spray plate 11 are both bolted to the sliding sleeve 16, the inside of the sliding sleeve 16 is slidably connected with the stabilizer bar 17, both ends of the stabilizer bar 17 are both bolted to the inside of the non-woven fabric treatment box 1, and the top and the bottom of both sides of the mouth-shaped spray plate 11 are both rotationally connected with the rubber roller 18.

In the downward moving process of the plug rod 14, water can enter the wringing cylinder 15 through the water inlet, water inside the wringing cylinder 15 is convenient to replace, the sliding sleeve 16 can slide on the stabilizing rod 17 in the driving process of the mouth-shaped spray plate 11 through the sliding sleeve 16, the mouth-shaped spray plate 11 can be limited in a left-right sliding manner through the sliding of the stabilizing rod 17 and the sliding sleeve 16, the mouth-shaped spray plate 11 can be stably moved left and right, the mouth-shaped spray plate 11 is prevented from shifting, the rubber roller 18 can be driven to move in the left-right moving process of the mouth-shaped spray plate 11, a cavity structure can be formed inside the mouth-shaped spray plate 11 through the rubber roller 18, the water-jet non-woven fabric belt 4 can be extruded through the rubber roller 18, and the disinfectant can be soaked in the water-jet non-woven fabric belt 4.

S1: the mouth spray plate 11 is communicated with a storage tank of disinfectant through a water pump, cleaning water is poured into a cavity at the right side inside the non-woven fabric treatment tank 1, the spun-laced non-woven fabric belt 4 passes through a guide roller group 6 inside the non-woven fabric treatment tank 1, and the spun-laced non-woven fabric belt 4 penetrates through the inside of the mouth spray plate 11;

S2: the power mechanism 2 can drive the winding wheel 7 and the winding wheel 8 to rotate through the transmission mechanism 3, the winding wheel 7 and the winding wheel 8 can drive the mouth-shaped spray plate 11 to move through the transmission rope 9, the mouth-shaped spray plate 11 can rapidly move left and right on the spun-laced non-woven fabric belt 4, and spray holes at the top and the bottom of the inner side of the mouth-shaped spray plate 11 are utilized to spray the spun-laced non-woven fabric belt 4 to disinfect the spun-laced non-woven fabric belt 4;

s3: the transmission mechanism 3 can drive the T-shaped frame 13 to rotate through the hinging rod 12, and the T-shaped frame 13 can drive water in the water squeezing cylinder 15 to flow through the plug rod 14, so that the water can quickly impact and clean the spun-laced non-woven fabric belt 4;

S4: the spun-laced non-woven fabric belt 4 is pulled out for drying after being disinfected and cleaned.

Working principle: the mouth-shaped spray plate 11 is communicated with a storage tank of disinfectant through a water pump, cleaning water is poured into a cavity on the right side inside the non-woven fabric treatment tank 1, the spun-laced non-woven fabric belt 4 penetrates through a guide roller group 6 inside the non-woven fabric treatment tank 1, the spun-laced non-woven fabric belt 4 is of a W-shaped structure, the spun-laced non-woven fabric belt 4 penetrates through the inside of the mouth-shaped spray plate 11, and the top end and the bottom end inside the mouth-shaped spray plate 11 are communicated with spray holes.

The power of gear motor 21 is switched on, gear motor 21 can drive worm 22 to rotate, worm 22 rotates the setting through bearing and non-woven fabrics processing case 1, let worm 22 can steadily rotate, avoid worm 22 to rock, worm 22 can drive worm wheel 23 clockwise rotation, worm wheel 23 can drive eccentric wheel 24 clockwise rotation, be eccentric structure between eccentric wheel 24 and the worm wheel 23, worm wheel 23 drives eccentric wheel 24 and rotates the in-process and drive eccentric wheel 24 down earlier and then drive eccentric wheel 24 upwards to remove, so reciprocate, eccentric wheel 24 can rotate and drive the connecting ring 25 to reciprocate in the inside of connecting ring 25, when connecting ring 25 moves down, connecting ring 25 can drive long rack 26 and reciprocate, long rack 26 slides in the inside of stop collar and is spacing, let long rack 26 can steadily reciprocate, let long rack 26 can mesh with connecting gear 27, connecting gear 27 anticlockwise rotation, connecting gear 27 can drive big sprocket 28 anticlockwise rotation, big sprocket 28 rotates through the inside setting of bearing and processing case 1, big sprocket 28 can drive big sprocket 28 anticlockwise rotation steadily, sprocket 29 can rotate anticlockwise.

The chain 29 can drive the small chain wheel 31 to rotate anticlockwise, the small chain wheel 31 is arranged in the non-woven fabric treatment box 1 in a rotating way through a bearing, the small chain wheel 31 can rotate steadily, a lug of the small chain wheel 31 can slide in a sliding hole of the T-shaped rack 32 in the rotating process of the small chain wheel 31 and drive the T-shaped rack 32 to move rightwards, then the T-shaped rack 32 is driven to rotate leftwards, so that the T-shaped rack 32 can drive the pinion 33 to rotate anticlockwise when the T-shaped rack 32 rotates rightwards, the pinion 33 can drive the winding wheel 7 to rotate anticlockwise, the winding wheel 7 is arranged in the non-woven fabric treatment box 1 in a rotating way through the bearing, the winding wheel 7 can rotate steadily, the rolling wheel 7 can roll the driving rope 9 to the right in the anticlockwise rotation process, the T-shaped rack 32 can drive the small fluted disc 34 to rotate anticlockwise, the small fluted disc 34 can drive the rolling wheel 8 to rotate anticlockwise, the driving rope 9 is discharged in the anticlockwise rotation process of the rolling wheel 8, the pulley 10 can guide the driving rope 9, the top of the driving rope 9 is horizontally arranged, the driving rope 9 is driven by the rolling wheel 7 and the rolling wheel 8 to rotate anticlockwise, the driving rope 9 can drive the mouth-shaped spray plate 11 to move leftwards, the mouth-shaped spray plate 11 can drive the sliding sleeve 16 to move leftwards, the sliding sleeve 16 slides on the surface of the stabilizing rod 17, and the mouth-shaped spray plate 11 can move leftwards and rightwards stably.

The small chain wheel 31 can drive the large bevel gear 35 to rotate clockwise, the large bevel gear 35 can drive the small bevel gear 36 to rotate, the small bevel gear 36 can drive the rotating rod 37 to rotate, the rotating rod 37 is arranged in a rotating way through the bearing and the partition plate 5, the rotating rod 37 can stably rotate, the rotating rod 37 can drive the main bevel gear 38 to rotate, the main bevel gear 38 and the auxiliary bevel gear 39 are bevel gears, the main bevel gear 38 and the auxiliary bevel gear 39 can be meshed, the main bevel gear 38 conveniently drives the auxiliary bevel gear 39 to rotate, the auxiliary bevel gear 39 is arranged in a rotating way through the bearing and the non-woven fabric treatment box 1, the auxiliary bevel gear 39 can stably rotate, the auxiliary bevel gear 39 and the hinging rod 12 are in an eccentric structure, the hinging rod 12 can drive the T-shaped frame 13 to positively and negatively rotate, the sliding holes of the T-shaped frame 13 can slide on the protruding blocks of the plug rod 14 and drive the plug rod 14 to move up and down, the plug rod 14 can move up and down in the water squeezing plug cylinder 15, the auxiliary bevel gear 39 can stably rotates with the non-woven fabric treatment box 1, the auxiliary bevel gear 39 can stably rotate along with the hinging rod 12, the water is steadily rotates along with the non-woven fabric through the water squeezing belt, and the water is washed by water flowing upwards, and the non-woven fabric is washed by the water flowing belt 4 after the water is washed.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims

1. The utility model provides a water thorn non-woven fabrics integration processing equipment, includes non-woven fabrics processing case (1) and inside sliding connection's of non-woven fabrics processing case (1 water thorn non-woven fabrics area (4), a serial communication port, the welding of the inside middle-end of non-woven fabrics processing case (1) has baffle (5), the inside left side rotation of non-woven fabrics processing case (1) is connected with rolling wheel (7), the inside rotation of non-woven fabrics processing case (1) is connected with rolling wheel (8), twining between rolling wheel (7) and rolling wheel (8) has driving rope (9), the top bolt of driving rope (9) has mouth-shaped spray board (11), the inside right side of non-woven fabrics processing case (1) articulates there is T type frame (13), the top of T type frame (13) articulates there is articulated pole (12), the slide hole at T type frame (13) both ends all sliding connection has cock stem (14), the surface sliding connection of cock stem (14) has a water squeezing drum (15), the bottom of water squeezing drum (15) side has water inlet (15) and water squeezing drum (16) top, water squeezing drum (16) side is connected with inside top (16) has top of the side of the stable bolt board (16), the two ends of the stabilizer bar (17) are both bolted with the inside of the non-woven fabric treatment box (1), the top and the bottom of two sides of the mouth-shaped spray plate (11) are both rotationally connected with rubber rollers (18), the left side of the non-woven fabric treatment box (1) is bolted with a power mechanism (2), the inside of the power mechanism (2) is meshed with a transmission mechanism (3), the winding wheel (7) and the winding wheel (8) are both bolted with the transmission mechanism (3), and the transmission mechanism (3) is hinged with a hinging rod (12);

The power mechanism (2) comprises a gear motor (21), a worm (22), a worm wheel (23), an eccentric wheel (24) and a connecting ring (25), wherein the right side of the gear motor (21) is in bolt connection with the left side of the non-woven fabric treatment box (1), the output end of the gear motor (21) penetrates through a hole in the left side of the non-woven fabric treatment box (1) and is in bolt connection with the left end of the worm (22), the right end of the surface of the worm (22) is meshed with the bottom of the worm wheel (23), the axle center of the rear side of the worm wheel (23) is in bolt connection with the right side of the axle center of the eccentric wheel (24), the outer side of the eccentric wheel (24) is in rotary sleeve connection with the inner side of the connecting ring (25), and the power mechanism (2) further comprises a connecting assembly hinged with the connecting ring (25);

The connecting assembly comprises a long rack (26), a connecting gear (27), a large chain wheel (28) and a chain (29), wherein the bottom of the connecting ring (25) is hinged to the top end of the long rack (26), teeth on the right side of the long rack (26) are meshed with teeth on the left side of the connecting gear (27), the rear side of the connecting gear (27) is bolted to the surface of the large chain wheel (28), the axis of the large chain wheel (28) is rotatably connected with the inside of the non-woven fabric treatment box (1), teeth of the large chain wheel (28) are meshed with the left side of the inside of the chain (29), and the chain (29) is meshed with the transmission mechanism (3);

the surface of the long rack (26) is connected with a limit sleeve in a sliding manner, the rear side of the limit sleeve is in bolt connection with the inside of the non-woven fabric treatment box (1), an eccentric structure is formed between the worm wheel (23) and the eccentric wheel (24), and the axis of the worm wheel (23) penetrates through a hole at the rear side of the eccentric wheel (24) and is in rotary connection with the inside of the non-woven fabric treatment box (1);

The transmission mechanism (3) comprises a small chain wheel (31), a T-shaped rack (32), a small gear (33) and a small fluted disc (34), wherein the right side of the inside of the chain (29) is meshed with teeth of the small chain wheel (31), the axle center of the small chain wheel (31) is rotationally connected with the inside of the non-woven fabric treatment box (1), a lug on the surface of the small chain wheel (31) is slidingly connected with a sliding hole of the T-shaped rack (32), the bottom end of the T-shaped rack (32) is hinged with the inside of the non-woven fabric treatment box (1), the left side of the middle end of the top of the T-shaped rack (32) is meshed with teeth at the bottom of the small gear (33), the rear side of the small gear (33) is bolted with the surface of the rolling wheel (7), the right side of the middle end of the top of the T-shaped rack (32) is meshed with the bottom of the small fluted disc (34), the rear side of the small fluted disc (34) is bolted with the surface of the rolling wheel (8), and the transmission mechanism (3) further comprises a driving component bolted with the small chain wheel (31);

the driving assembly comprises a large conical gear (35), a small conical gear (36), a rotating rod (37), a main helical gear (38) and a secondary helical gear (39), wherein the rear side of the small chain wheel (31) is in bolt connection with the surface of the large conical gear (35), the teeth on the right side of the large conical gear (35) are meshed with the teeth on the rear side of the small conical gear (36), the shaft center of the right side of the small conical gear (36) is in bolt connection with the left end of the rotating rod (37), the surface of the rotating rod (37) is in rotary sleeve connection with a hole of the partition plate (5), the right end of the rotating rod (37) extends to the right side of the inside of the non-woven fabric processing box (1) and is in bolt connection with the shaft center of the left side of the main helical gear (38), the teeth on the top of the main helical gear (38) are meshed with the teeth on the bottom of the secondary helical gear (39), the shaft center of the secondary helical gear (39) is in rotary connection with the inside of the non-woven fabric processing box (1), and the top end of the secondary helical gear (39) is in rotary connection with the hinging rod (12) on the surface of the secondary helical gear (39);

The T-shaped rack (32) is composed of a sliding frame and an arc-shaped rack at the top of the sliding frame, a sliding hole of the sliding frame is in sliding connection with a lug on the surface of a small chain wheel (31), the bottom of a small gear (33) is meshed with the top of the arc-shaped rack, the bottom of a small fluted disc (34) is meshed with the top of the arc-shaped rack, a small bevel gear (36) is positioned at the rear side of the T-shaped rack (32), and a rotating rod (37) is positioned at the rear side of a water squeezing cylinder (15);

The inside rotation of non-woven fabrics processing case (1) is connected with guide roller group (6), the surface of water thorn non-woven fabrics area (4) and the inside sliding connection of guide roller group (6), the inside both sides of driving rope (9) all sliding connection have pulley (10), the axle center department of pulley (10) is rotated with the inside of non-woven fabrics processing case (1) and is connected.

2. The working method of the integrated processing equipment for the spun-laced non-woven fabrics according to claim 1, which is characterized by comprising the following steps:

S1: the mouth-shaped spray plate (11) is communicated with a storage tank of disinfectant through a water pump, cleaning water is poured into a cavity at the right side inside the non-woven fabric treatment tank (1), the spun-laced non-woven fabric belt (4) passes through a guide roller set (6) inside the non-woven fabric treatment tank (1), and the spun-laced non-woven fabric belt (4) penetrates through the inside of the mouth-shaped spray plate (11);

S2: the power mechanism (2) drives the winding wheel (7) and the winding wheel (8) to rotate through the transmission mechanism (3), the winding wheel (7) and the winding wheel (8) drive the mouth-shaped spray plate (11) to move through the transmission rope (9), the mouth-shaped spray plate (11) moves left and right rapidly on the spun-laced non-woven fabric belt (4), and spray holes at the top and the bottom of the inner side of the mouth-shaped spray plate (11) are utilized to spray the spun-laced non-woven fabric belt (4) to disinfect the spun-laced non-woven fabric belt (4);

S3: the transmission mechanism (3) drives the T-shaped frame (13) to rotate through the hinging rod (12), and the T-shaped frame (13) drives water in the water squeezing cylinder (15) to flow through the plug rod (14), so that the water can rapidly impact and clean the spun-laced non-woven fabric belt (4);

S4: the spun-laced non-woven fabric belt (4) is pulled out for drying after being disinfected and cleaned.