阅读说明：本技术 一种纺织品干燥处理装置 (Textile drying treatment device ) 是由 胡方 于 2021-09-23 设计创作，主要内容包括：本发明涉及纺织品干燥技术领域,特别涉及一种纺织品干燥处理装置,包括底部机架、转动脱水机构、脱水筒、再处理机构以及收集框,本发明中转动脱水机构的转轴在转动过程中会带动脱水筒转动,脱水筒转动产生的离心力可以对脱水筒内部的纺织品进行脱水处理；振动支链中的旋转辊在转动过程中通过拨动圆盘带动推板进行前后往复移动,推板前后往复移动过程中对纺织品进行振荡处理,纺织品振荡过程中可以将其内部的水分振荡出来,进一步提高纺织品的脱水效果。(The invention relates to the technical field of textile drying, in particular to a textile drying treatment device, which comprises a bottom rack, a rotary dehydration mechanism, a dehydration cylinder, a reprocessing mechanism and a collection frame, wherein a rotating shaft of the rotary dehydration mechanism can drive the dehydration cylinder to rotate in the rotating process, and the textile inside the dehydration cylinder can be dehydrated by centrifugal force generated by the rotation of the dehydration cylinder; the rotating roller in the vibrating branch chain drives the push plate to reciprocate back and forth in the rotating process through the poking disc, the textile is subjected to oscillation treatment in the reciprocating process of the push plate, and the moisture in the textile can be oscillated in the oscillation process of the textile, so that the dewatering effect of the textile is further improved.)

1. The utility model provides a textile drying treatment device, includes bottom frame (1), rotates dewatering mechanism (2), dewatering cylinder (3), retreatment mechanism (4) and collection frame (5), its characterized in that: the automatic dewatering device is characterized in that a rotary dewatering mechanism (2) is installed on the upper end face of the bottom rack (1), a dewatering drum (3) is installed on the upper end of the rotary dewatering mechanism (2), a rectangular cavity structure is arranged inside the dewatering drum (3), water outlets (6) are evenly formed in the circumferential direction of the lower end face of the dewatering drum (3), a retreating mechanism (4) is installed inside the dewatering drum (3), a collecting frame (5) is installed on the upper end face of the bottom rack (1) and located below the water outlets (6), the collecting frame (5) is of an annular structure, and the rotary dewatering mechanism (2) is located on the inner side of the collecting frame (5); wherein:

the rotary dehydration mechanism (2) comprises a rotary motor (21), a rotating shaft (22), a first belt wheel (23), a belt (24), a sliding plate (25), a limiting spring rod (26), a connecting shaft (27), a second belt wheel (28), a rotating shaft (29) and a limiting block (210), wherein the rotating shaft (22) is installed in the middle of the upper end face of the bottom rack (1) through a bearing, a dehydration cylinder (3) is installed at the upper end of the rotating shaft (22), the rotary motor (21) is installed on the bottom rack (1) through a motor base, the sliding plate (25) is arranged on the upper end face of the bottom rack (1) in a sliding mode, the limiting spring rod (26) is installed between the sliding plate (25) and the upper end face of the bottom rack (1), the connecting shaft (27) is installed on the sliding plate (25) through a bearing, the rotating shaft (29) is installed at the upper end of an output shaft of the rotary motor (21), and the first belt wheel (23) are installed on the rotating shaft (22) and the connecting shaft (27), the second belt wheel (28) is rotatably arranged on the rotating shaft (29) in a threaded connection mode, a belt (24) is arranged between the first belt wheel (23) and the second belt wheel (28), a limiting block (210) is arranged on the rotating shaft (29) through threads, and the second belt wheel (28) is composed of a plurality of belt wheel discs with different diameters;

the retreating mechanism (4) comprises a rotating motor (41), a fixed connecting block (42), a rotating connecting block (43), a placing roller (44), a winding roller (45) and a vibrating branched chain (46), wherein the rotating motor (41) is installed on the right side of the inner lower end face of the dewatering cylinder (3) through a motor base, the fixed connecting block (42) is installed on the front side of the inner lower end face of the dewatering cylinder (3) through a bearing, the placing roller (44) is connected to the fixed connecting block (42) in a clamped mode, the rotating connecting block (43) is installed on an output shaft of the rotating motor (41), the winding roller (45) is connected to the rotating connecting block (43) in a clamped mode, and the vibrating branched chain (46) is installed on the inner lower end face of the dewatering cylinder (3).

2. A textile drying treatment apparatus as claimed in claim 1, wherein: the vibrating branched chain (46) comprises a vibrating frame (461), a third belt wheel (462), a linkage belt (463), a rotating roller (464), a toggle disc (465), a telescopic spring rod (466) and a push plate (467), the automatic dewatering device is characterized in that the vibrating frame (461) is installed on the lower end face inside the dewatering cylinder (3), the middle part of the front end face of the vibrating frame (461) is rotatably provided with a rotating roller (464) through a bearing, the rotating roller (464) and a driving shaft of a rotating motor (41) are respectively provided with a third belt wheel (462), a linkage belt (463) is installed on the third belt wheel (462), the rotating roller (464) is fixedly provided with a stirring disc (465), stirring teeth are evenly arranged on the side wall of the stirring disc (465), the telescopic spring rods (466) are installed on the vibrating frame (461) in a vertically symmetrical mode, the telescopic spring rods (466) are provided with push plates (467), and the stirring teeth abut against the push plates (467).

3. A textile drying treatment apparatus as claimed in claim 1, wherein: and a drying plate (33) is arranged on the inner wall of the dewatering cylinder (3).

4. A textile drying treatment apparatus according to claim 2, wherein: the left side of the front end face of the vibrating rack (461) is provided with a tensioning spring rod (4611) in an up-and-down symmetrical mode, the front end face of the tensioning spring rod (4611) is provided with a fixing block (4612), a tensioning roller (4613) is rotatably arranged between the upper fixing block (4612) and the lower fixing block (4612), the right side of the front end face of the vibrating rack (461) is provided with a support frame (4614) in an up-and-down symmetrical mode, and a rotating roller (4615) is rotatably arranged between the upper support frame (4614) and the lower support frame (4614).

5. A textile drying treatment apparatus as claimed in claim 1, wherein: the upper end surface of the dewatering cylinder (3) is connected with a cover plate (31) in a clamping mode, a round through groove is formed in the cover plate (31) and located above a placing roller (44) and a winding roller (45), rotating blocks (32) are installed inside the round through groove in a rotating mode through bearings, and the two rotating blocks (32) are connected with the placing roller (44) and the winding roller (45) in a clamping mode respectively.

6. A textile drying treatment apparatus as claimed in claim 1, wherein: one side of the upper end surface of the collecting frame (5) close to the rotary dewatering mechanism (2) is provided with a flow baffle (51).

7. A textile drying treatment apparatus as claimed in claim 1, wherein: waterproof board (34) are installed to dewatering cylinder (3) inside wall bilateral symmetry, and waterproof board (34) are Contraband type structure, carry logical groove (341) have been seted up to waterproof board (34) opposite face, and place inside roller (44) and winding roller (45) all are located waterproof board (34).

8. A textile drying treatment apparatus according to claim 7, wherein: the conveying through groove (341) is symmetrically provided with circular arc bulges (342) in front and back.

9. A textile drying treatment apparatus as claimed in claim 1, wherein: the rotating shaft (22) is evenly provided with a plurality of groups of supporting connecting frames (221) along the circumferential direction, and the upper ends of the supporting connecting frames (221) are connected with the lower end surface of the dewatering cylinder (3).

Technical Field

The invention relates to the technical field of textile drying, in particular to a textile drying treatment device.

Background

The textile is a product which is made by processing textile raw materials such as yarn, thread, natural silk, rayon, chemical fiber filament and staple, stretch yarn, metal wire and the like through the steps of impurity removal, summarization, opening, carding, twisting, dyeing, washing, drying, winding and the like, and is roughly divided into knitted fabrics, woven fabrics, non-woven fabrics, natural fur shell fabrics, plastic fabrics, industrial fabrics, agricultural fabrics, medical textiles and the like, and is widely applied to daily production and life of people.

At present, the following problems exist in the drying process of textiles: a. the method comprises the steps that after the textile is processed and cleaned, the textile needs to be subjected to blast heating drying treatment, the textile is subjected to drying treatment by a method of prolonging a blast heating path in the traditional textile drying process, the drying time is long, the occupied space is large, the drying effect of the textile is poor, and the drying cost is high; b. because the textile has good water absorption, the internal water of the textile is more in the cleaning process, and the internal water of the textile is difficult to diffuse out in the drying process, so that the drying effect of the textile is poor.

Disclosure of Invention

In order to achieve the purpose, the invention adopts the following technical scheme: the utility model provides a fabrics drying process device, includes bottom frame, rotation dehydration mechanism, dehydration section of thick bamboo, retreatment mechanism and collection frame, bottom frame up end install and rotate dehydration mechanism, rotate dehydration mechanism upper end and install the dehydration section of thick bamboo, the inside rectangle cavity structure that sets up of dehydration section of thick bamboo, the delivery port has evenly been seted up to terminal surface circumference under the dehydration section of thick bamboo, dehydration section of thick bamboo internally mounted has retreatment mechanism, bottom frame up end just is located the delivery port below and installs the collection frame, the collection frame is the loop configuration, and it is inboard that the rotation dehydration mechanism is located the collection frame.

The rotary dehydration mechanism comprises a rotary motor, a rotating shaft, a first belt wheel, a belt, a sliding plate, a limiting spring rod, a connecting shaft, a second belt wheel, a rotating shaft and a limiting block, the rotating shaft is installed in the middle of the upper end face of the bottom rack through a bearing, the dewatering cylinder is installed at the upper end of the rotating shaft, the rotating motor is installed on the bottom rack through a motor base, the sliding plate is arranged on the upper end face of the bottom rack in a sliding mode, a limiting spring rod is installed between the sliding plate and the upper end face of the bottom rack, a connecting shaft is installed on the sliding plate through a bearing, a rotating shaft is installed at the upper end of an output shaft of the rotating motor, a first belt wheel is installed on the rotating shaft and the connecting shaft, a second belt wheel is installed on the rotating shaft in a rotating mode through a threaded connection mode, a belt is installed between the first belt wheel and the second belt wheel, a limiting block is installed on the rotating shaft through threads, and the second belt wheel comprises a plurality of belt wheel discs with different diameters.

The retreating mechanism comprises a rotating motor, a fixed connecting block, a rotating connecting block, a placing roller, a winding roller and a vibrating branched chain, wherein the rotating motor is installed on the right side of the lower end face inside the dewatering cylinder through a motor base, the fixed connecting block is installed on the front side of the lower end face inside the dewatering cylinder through a bearing, the placing roller is clamped on the fixed connecting block in a limiting mode, the rotating connecting block is installed on an output shaft of the rotating motor, the winding roller is clamped on the rotating connecting block in a limiting mode, and the vibrating branched chain is installed on the lower end face inside the dewatering cylinder.

Preferably, the vibration branch chain include vibration frame, No. three band pulleys, interlocking belt, rotatory roller, stir disc, expanding spring pole and push pedal, wherein vibration rack-mount terminal surface under the dehydrating cylinder is inside, the terminal surface middle part is rotated through the bearing and is installed rotatory roller before the vibration frame, install No. three band pulleys respectively in rotatory roller and the rotating electrical machines drive shaft, install the interlocking belt on No. three band pulleys, the disc is stirred to fixed being provided with on the rotatory roller, stir evenly to be provided with on the disc lateral wall and stir the tooth, expanding spring pole longitudinal symmetry installs in the vibration frame, install the push pedal on the expanding spring pole, and stir the tooth and lean on the push pedal.

Preferably, the vibrating rack before the terminal surface left side longitudinal symmetry install the tensioning spring beam, the fixed block is installed to the terminal surface before the tensioning spring beam, rotate between two upper and lower fixed blocks and install the tensioning roller, the support frame is installed to the terminal surface right side longitudinal symmetry before the vibrating rack, rotate between two upper and lower support frames and install the live-rollers, the tensioning roller can prolong the textile in the route that spin-dries of dewatering tube with the live-rollers mutually supporting, increase the effect that spin-dries of textile, wherein the tensioning roller makes the textile be in tight state all the time through tensioning spring beam and fixed block mutually supporting, avoid the textile to take place not hard up situation, influence the transport effect of textile on placing roller and winding roller.

Preferably, the inner wall of the dewatering cylinder is provided with a drying plate, and the drying plate can accelerate the evaporation speed of the moisture on the surface of the textile and improve the drying efficiency of the textile.

Preferably, the upper end face of the dewatering cylinder is clamped with a cover plate, the cover plate is provided with a circular through groove above the placing roller and the winding roller, a rotating block is rotatably installed in the circular through groove through a bearing, and the rotating block is respectively clamped with the placing roller and the winding roller.

Preferably, the flow baffle is installed on the upper end surface of the collecting frame and on one side close to the rotary dewatering mechanism, and the flow baffle can be used for avoiding the splashing situation of water drops generated by spin-drying, such as the situation that if the water drops into the rotary dewatering mechanism, the internal parts of the rotary dewatering mechanism are damaged.

Preferably, dewatering cylinder inside wall bilateral symmetry install the waterproof board, and the waterproof board is Contraband type structure, the transport logical groove has been seted up to the waterproof board opposite face, and place the roller and all be located inside the waterproof board with the winding roller, the use of waterproof board can avoid spin-drying the moisture that produces to enter into again and place the inside relatively poor situation that leads to the dry effect of fabrics on roller and the winding roller.

Preferably, the conveying through groove is symmetrically provided with circular arc bulges in the front and back, the textiles can be protected by the circular arc bulges, and the condition that the textile quality is influenced by abrasion of the textiles in the conveying through groove process is avoided.

Preferably, the pivot evenly be provided with the multiunit along its circumference and support even frame, support even frame upper end and dewatering cylinder lower extreme face and be connected, support even use of frame and can play the supporting role to the dewatering cylinder for the dewatering cylinder is more stable at the rotation in-process, avoids the dewatering cylinder to rotate the in-process and takes place to rock the situation that causes the dewatering cylinder to drop from the pivot, in order to avoid the emergence of incident.

The invention has the beneficial effects that: 1. according to the invention, the rotating shaft of the rotating dehydration mechanism can drive the dehydration cylinder to rotate in the rotation process, and the centrifugal force generated by the rotation of the dehydration cylinder can carry out dehydration treatment on textiles in the dehydration cylinder; the rotating roller in the vibrating branch chain drives the push plate to reciprocate back and forth in the rotating process through the poking disc, the textile is subjected to oscillation treatment in the reciprocating process of the push plate, and the moisture in the textile can be oscillated in the oscillation process of the textile, so that the dewatering effect of the textile is further improved.

2. In the rotary dehydration mechanism designed by the invention, the rotation of the dehydration cylinder can drive the textile to carry out dehydration operation, wherein the second belt wheel is composed of belt wheels with different diameters, and the first belt wheel is matched with the belt to ensure that the rotating shaft obtains different rotating speeds, so that the dehydration cylinder obtains different rotating speeds, the rotating speed of the dehydration cylinder can be changed according to the water absorption amount of the textile, and the dehydration effect of the textile is improved under the condition of ensuring the reasonable rotating speed of the dehydration cylinder.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a front view of the present invention.

Fig. 2 is a schematic perspective view of the present invention.

FIG. 3 is a schematic perspective view of the rotary dewatering mechanism and the collecting frame of the present invention.

Figure 4 is a schematic perspective view of the reprocessing mechanism of the present invention and dewatering drum.

Figure 5 is a schematic view of the structure between the reprocessing mechanism and the dewatering cylinder of the present invention.

Fig. 6 is a partial enlarged view of fig. 4 a according to the present invention.

Fig. 7 is a front view of the flashing of the present invention.

Fig. 8 is a cross-sectional view taken at B-B of fig. 7 in accordance with the present invention.

In the figure: 1. a bottom chassis; 2. rotating the dewatering mechanism; 21. rotating the motor; 22. a rotating shaft; 221. a support connecting frame; 23. a first belt wheel; 24. a belt; 25. a sliding plate; 26. a limiting spring rod; 27. a connecting shaft; 28. a second belt wheel; 29. a rotating shaft; 210. a limiting block; 3. a dewatering drum; 31. a cover plate; 32. rotating the block; 33. drying the plate; 34. a waterproof sheet; 341. a conveying through groove; 342. a circular arc-shaped bulge; 4. a reprocessing mechanism; 41. a rotating electric machine; 42. fixing a connecting block; 43. rotating the connecting block; 44. placing a roller; 45. a winding roller; 46. vibrating the branched chain; 461. vibrating the frame; 4611. tensioning the spring rod; 4612. a fixed block; 4613. a tension roller; 4614. a support frame; 4615. a rotating roller; 462. a third belt wheel; 463. a linkage belt; 464. a rotating roller; 465. shifting the disc; 466. a telescoping spring rod; 467. pushing the plate; 5. a collection frame; 51. a flow baffle plate; 6. and (7) a water outlet.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

Referring to fig. 1 and 4, a textile drying treatment device, including bottom frame 1, rotation dewatering mechanism 2, dewatering cylinder 3, retreatment mechanism 4 and collection frame 5, 1 up end of bottom frame install and rotate dewatering mechanism 2, rotate dewatering mechanism 2 upper end and install dewatering cylinder 3, the inside rectangle cavity structure that sets up of dewatering cylinder 3, delivery port 6 has evenly been seted up to dewatering cylinder 3 lower terminal surface circumference, dewatering cylinder 3 internally mounted has retreatment mechanism 4, 1 up end of bottom frame just is located delivery port 6 below and installs collection frame 5, collection frame 5 is the loop configuration, and it is inboard that rotation dewatering mechanism 2 is located collection frame 5.

Referring to fig. 4, the drying plate 33 is installed on the inner wall of the dewatering cylinder 3, and the use of the drying plate 33 can accelerate the evaporation speed of the moisture on the surface of the textile and improve the drying efficiency of the textile.

Referring to fig. 3, the rotary dewatering mechanism 2 includes a rotary motor 21, a rotary shaft 22, a first belt wheel 23, a belt 24, a sliding plate 25, a limiting spring rod 26, a connecting shaft 27, a second belt wheel 28, a rotary shaft 29 and a limiting block 210, wherein the rotary shaft 22 is mounted in the middle of the upper end surface of the bottom frame 1 through a bearing, the dewatering cylinder 3 is mounted at the upper end of the rotary shaft 22, the rotary motor 21 is mounted on the bottom frame 1 through a motor base, the sliding plate 25 is slidably disposed on the upper end surface of the bottom frame 1, the limiting spring rod 26 is mounted between the sliding plate 25 and the upper end surface of the bottom frame 1, the connecting shaft 27 is mounted on the sliding plate 25 through a bearing, the rotary shaft 29 is mounted at the upper end of the output shaft of the rotary motor 21, the first belt wheel 23 is mounted on the rotary shaft 22 and the connecting shaft 27, the second belt wheel 28 is rotatably mounted on the rotary shaft 29 through a threaded connection, the belt 24 is mounted between the first belt wheel 23 and the second belt wheel 28, install stopper 210 through the screw thread on the axis of rotation 29, stopper 210 quantity is two, two stopper 210 are located the upper and lower both ends of No. two band pulleys 28 respectively, wherein No. two band pulleys 28 comprise the pulley dish of a plurality of different diameters, mutually support through a band pulley 23 and belt 24 and make pivot 22 obtain different rotational speeds, make dewatering cylinder 3 obtain different rotational speeds, so according to the textile absorb water how much can change dewatering cylinder 3's rotational speed, improve the dehydration effect of textile under the condition of guaranteeing the reasonable rotational speed of dewatering cylinder 3.

Referring to fig. 1, the rotating shaft 22 is uniformly provided with a plurality of groups of supporting connecting frames 221 along the circumferential direction, the upper ends of the supporting connecting frames 221 are connected with the lower end surface of the dewatering cylinder 3, and the supporting connecting frames 221 can play an auxiliary supporting role for the dewatering cylinder 3, so that the dewatering cylinder 3 is more stable in the rotating process, the situation that the dewatering cylinder 3 falls off from the rotating shaft 22 is avoided, and safety accidents are avoided.

Referring to fig. 5, the reprocessing mechanism 4 includes a rotating motor 41, a fixed connection block 42, a rotating connection block 43, a placing roller 44, a winding roller 45 and a vibrating branched chain 46, wherein the rotating motor 41 is installed on the right side of the lower end face inside the dewatering cylinder 3 through a motor base, the fixed connection block 42 is installed on the front side of the lower end face inside the dewatering cylinder 3 through a bearing, the placing roller 44 is in limit clamping connection with the fixed connection block 42, the rotating connection block 43 is installed on an output shaft of the rotating motor 41, the winding roller 45 is in limit clamping connection with the rotating connection block 43, and the vibrating branched chain 46 is installed on the lower end face inside the dewatering cylinder 3.

Referring to fig. 2, the cover plate 31 is clamped on the upper end face of the dewatering cylinder 3, circular through grooves are formed in the cover plate 31 and located above the placing roller 44 and the winding roller 45, rotating blocks 32 are rotatably mounted in the circular through grooves through bearings, and the rotating blocks 32 are respectively clamped with the placing roller 44 and the winding roller 45.

Referring to fig. 4 and 6, the vibrating branched chain 46 includes a vibrating frame 461, a third belt wheel 462, a linkage belt 463, a rotating roller 464, a shifting disc 465, a telescopic spring rod 466 and a pushing plate 467, wherein the vibrating frame 461 is installed on the lower end surface inside the dewatering cylinder 3, the rotating roller 464 is rotatably installed in the middle of the front end surface of the vibrating frame 461 through a bearing, the third belt wheel 462 is installed on the rotating roller 464 and the driving shaft of the rotating motor 41 respectively, the linkage belt 463 is installed on the third belt wheel 462, the shifting disc 465 is fixedly installed on the rotating roller 464, shifting teeth are uniformly arranged on the side wall of the shifting disc 465, the telescopic spring rod 466 is installed on the vibrating frame 461 in an up-and-down symmetrical manner, the pushing plate 467 is installed on the telescopic spring rod 466, and the shifting teeth abut against the pushing plate 467.

Referring to fig. 4, the left side of the front end surface of the vibrating frame 461 is provided with the tensioning spring rods 4611 in a vertically symmetrical manner, the front end surface of the tensioning spring rods 4611 is provided with the fixing blocks 4612, the tensioning rollers 4613 are rotatably mounted between the upper and lower fixing blocks 4612, the right side of the front end surface of the vibrating frame 461 is provided with the supporting frames 4614 in a vertically symmetrical manner, the rotating rollers 4615 are rotatably mounted between the upper and lower supporting frames 4614, the tensioning rollers 4613 and the rotating rollers 4615 are matched with each other to extend the spin-drying path of the textile on the dewatering cylinder 3 and increase the spin-drying effect of the textile, wherein the tensioning rollers 4613 and the tensioning spring rods 4611 are matched with each other to keep the textile in a tight state all the time, so as to avoid the loosening of the textile and influence the conveying effect of the textile on the placing rollers 44 and the winding rollers 45.

During the specific work, the winding roller 45 and the placing roller 44 wound with the wet textiles are respectively clamped on the fixed connecting block 42 and the rotating connecting block 43 through manual work, the textiles pass through the vibration branched chain 46 to be wound on the winding roller 45, the cover plate 31 is placed on the upper end surface of the dewatering cylinder 3, the upper ends of the placing roller 44 and the winding roller 45 are respectively and fixedly clamped on the rotating block 32, the cover plate 31 can support the placing roller 44 and the winding roller 45, the situation that the placing roller 44 and the winding roller 45 shake in the rotating process to influence the textile conveying effect is avoided, the second belt wheel 28 moves up and down on the rotating shaft 29 according to the rotating speed required by the dewatering cylinder 3 in the rotating process, the belt wheel discs with different diameters on the second belt wheel 28 move to proper positions, and the belt 24 is adjusted to move to proper positions on the first belt wheel 23 and the second belt wheel 28, the sliding plate 25 is driven to move by the limiting spring rod 26 in the moving process of the belt 24, so that the belt 24 is always in a tight state, the situation that the transmission effect of the belt 24 is influenced by looseness of the belt 24 in the adjusting process of the second belt wheel 28 is avoided, after the adjusting process of the second belt wheel 28 is finished, the rotating motor 21 is started to drive the rotating shaft 29 to rotate, the rotating shaft 29 drives the rotating shaft 22 to rotate by mutual matching of the first belt wheel 23, the second belt wheel 28 and the belt 24 in the rotating process, the rotating shaft 22 drives the dewatering cylinder 3 to rotate in the rotating process, the textiles in the dewatering cylinder 3 are centrifugally dewatered by centrifugal force generated in the rotating process, wherein the situation that the transmission effect of the second belt wheel 28 is influenced by up-and-down spiral rotation of the second belt wheel 28 in the rotating process is avoided by the use of the limiting block 210, the rotating motor 41 is synchronously started in the rotating process of the dewatering cylinder 3, and the rotating motor 41 drives the winding roller 45 to rotate by the rotating connecting block 43 in the rotating process, winding roller 45 is rotating the in-process and carrying out the coiling processing to the fabrics after dewatering tube 3 spin-dries, the fabrics is at the removal in-process, rotating electrical machines 41 is through No. three band pulleys 462 and linkage area 463 cooperate each other and drive rotatory roller 464 and rotate, rotatory roller 464 rotates in-process drive stir disc 465 and rotates, stir disc 465 and drive push pedal 467 at the rotation in-process and carry out reciprocating motion back and forth, push pedal 467 reciprocating motion in-process can carry out the vibration processing to the fabrics, the fabrics oscillation in-process can come out its inside moisture, ensure that the fabrics can fully take off its inside moisture, and then improve the dewatering effect of fabrics, wherein telescopic spring rod 466 plays resetting and supporting role to push pedal 467, the moisture that produces among the drying process drops into through delivery port 6 and collects frame 5.

Referring to fig. 4, the waterproof boards 34 are symmetrically installed on the left side and the right side of the inner side wall of the dewatering cylinder 3, the waterproof boards 34 are Contraband-shaped structures, the conveying through grooves 341 are formed in the opposite surfaces of the waterproof boards 34, the placing rollers 44 and the winding rollers 45 are both located inside the waterproof boards 34, and the waterproof boards 34 can avoid the situation that moisture generated by spin-drying enters the textile on the placing rollers 44 and the winding rollers 45 again to cause poor textile drying effect.

Referring to fig. 8, the front and back of the conveying through groove 341 are symmetrically provided with arc-shaped protrusions 342, and the arrangement of the arc-shaped protrusions 342 can protect the textiles, so as to avoid the situation that the textiles are worn during passing through the conveying through groove 341, so as to avoid affecting the quality of the textiles.

Referring to fig. 1, a baffle plate 51 is installed on a side of the upper end surface of the collecting frame 5 close to the rotary dewatering mechanism 2, and the baffle plate 51 can prevent water drops generated by spin-drying from splashing, for example, if the water drops fall into the rotary dewatering mechanism 2, the water drops will damage parts inside the rotary dewatering mechanism 2.

The invention also comprises the following steps in the drying process of the textile: the first step is as follows: placing treatment: the winding roller 45 and the placing roller 44 wound with the wet textiles are respectively clamped on the rotating connecting block 43 and the fixed connecting block 42 by manpower, and then the textiles pass through the conveying through groove 341 and are wound on the winding roller 45 by sequentially passing through the tensioning roller 4613, the rotating roller 464 and the rotating roller 4615.

The second step is that: spin-drying treatment: the rotating shaft 22 drives the textile inside the dewatering cylinder 3 to perform rotary dewatering and drying treatment in the rotating process.

The third step: refining treatment: rotatory roller 464 rotates the in-process and drives push plate 467 through stirring disc 465 and carry out reciprocating motion back and forth, and the reciprocating motion in-process can carry out the vibration processing to fabrics back and forth to push plate 467.

The fourth step: collecting and treating: after the textile drying is finished, the cover plate 31 is opened to remove the placing roller 44 and the winding roller 45, and then a new placing roller 44 and a new winding roller 45 are placed in the dewatering cylinder 3, and the actions are repeated.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention; any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.