A shock-absorbing and noise-reducing dewatering machine for cloth printing and dyeing

By setting an inner drum functional ring and a pressing mechanism at the top of the inner drum of the dewatering machine, the problem of low dewatering efficiency caused by fabric entanglement is solved, and the dewatering quality is improved.

CN224395243UActive Publication Date: 2026-06-23XIN CHENG RAN ZHI FU JIAN YOU XIAN GONG SI

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XIN CHENG RAN ZHI FU JIAN YOU XIAN GONG SI
Filing Date
2025-08-18
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Inside the dewatering machine, the fabric becomes entangled into a dense cluster structure due to centrifugal force, making it difficult to remove moisture and increasing the residual moisture content of the fabric after dewatering.

Method used

An inner chamber functional ring is set at the top of the inner chamber of the dewatering machine, with positioning screw holes distributed in a ring. A fitting pad is installed, and the fabric is restricted at one end by a pressing mechanism to reduce tangling and stacking and improve dewatering efficiency.

Benefits of technology

By limiting fabric entanglement and reducing the formation of clumps, the dehydration quality is improved, and the residual moisture content of the fabric after dehydration is reduced.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model belongs to cloth dewatering machine technical field especially for a kind of shock absorption and noise reduction dewatering machine for cloth printing and dyeing.The utility model includes dewatering machine shell and the dewatering machine inner container being set in dewatering machine shell, further includes: the top of dewatering machine inner container is fixed with the inside of inner container function ring, and the surface of inner container function ring is equipped with positioning screw hole part;The surface of the pad plate is attached to the surface of inner container function ring, and the surface of the pad plate is equipped with pad plate main groove, and the inside of pad plate main groove is equipped with locking mechanism, and the top of the pad plate is equipped with pressing mechanism.The utility model is by inserting the one end of cloth to the pad plate, and by pressing head pressing in support top tab plate, to realize the one end of cloth is positioned, thus under the action of centrifugal force, a large number of cloth is limited in one end, and the cloth under centrifugal force can reduce because of free floating, and the mutual entangling situation caused by stacking, so it is more difficult to form mass structure, improve dewatering quality.
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Description

Technical Field

[0001] This utility model relates to the technical field of fabric dewatering machines, specifically a shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing. Background Technology

[0002] The dewatering machine is one of the most important pieces of equipment in the textile printing and dyeing industry. Its core function is to remove excess water from the fabric through efficient centrifugal dewatering. The dewatering machine generates centrifugal force through the high-speed rotating dewatering drum (inner drum), which causes the water in the fabric to be thrown out through the mesh of the drum wall, collected in the outer drum and discharged, thus achieving dewatering.

[0003] Inside the dehydrator, the fabric will become entangled due to centrifugal force. The entangled fabric will squeeze and pile up, forming a dense clump structure, making it difficult for water to be thrown out of the fabric through centrifugal force (especially the fabric in the center of the entanglement). This will significantly increase the residual moisture content of the fabric after dehydration.

[0004] Therefore, we propose a shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing to solve the above problems. Utility Model Content

[0005] (a) Technical problems to be solved

[0006] To address the shortcomings of existing technologies, this utility model provides a shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing. It solves the problem mentioned in the background technology that, in the dewatering machine, the fabric will become entangled due to centrifugal force. The entangled fabric will squeeze and stack each other, forming a dense clump structure, making it difficult for water to be thrown out of the fabric through centrifugal force (especially the fabric in the center of the entanglement). This will significantly increase the residual moisture content of the fabric after dewatering.

[0007] (II) Technical Solution

[0008] To achieve the above objectives, this utility model specifically adopts the following technical solution:

[0009] A shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing includes a dewatering machine outer shell and a dewatering machine inner liner disposed inside the dewatering machine outer shell, and further includes: an inner liner functional ring fixedly disposed on the top of the dewatering machine inner liner, and the surface of the inner liner functional ring having a positioning screw hole portion.

[0010] The bonding pad is bonded to the surface of the inner liner functional ring, and the surface of the bonding pad has a main groove. A locking mechanism is provided inside the main groove, and a pressing mechanism is provided on the top of the bonding pad.

[0011] Furthermore, the positioning screw holes are distributed in a ring at equal intervals on the inclined surface of the inner liner functional ring, and the back of the fitting pad is fitted to the arc surface of the positioning screw holes.

[0012] Furthermore, the locking mechanism includes a pad side groove, a mounting pad, and a locking screw. The pad side groove is located at the top of the main groove of the pad, the mounting pad fits into the groove of the pad side groove, and the locking screw is longitudinally inserted through the center of the mounting pad.

[0013] Furthermore, the main groove of the pad is V-shaped, and the center of the mounting plate has a screw hole that matches the thread of the locking screw.

[0014] Furthermore, the clamping mechanism includes a pad support column, a support top plate, a clamping screw, and a clamping head. The pad support column is fixed to the top end of the pad, and the support top plate is fixed to the top of the pad support column. The clamping screw is longitudinally inserted through the center of the support top plate, and the clamping head is connected to the bottom of the clamping screw.

[0015] Furthermore, the two sets of pad support columns are V-shaped respectively, and the locking screw is located in the middle gap between the two sets of pad support columns.

[0016] Furthermore, the bottom of the mating pad is fixed with an upwardly extending support top protrusion, and the maximum extension position of the pressing head is located inside the support top protrusion.

[0017] (III) Beneficial Effects

[0018] Compared with the prior art, this utility model provides a shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing, which has the following beneficial effects:

[0019] This invention features an annular inner drum functional ring at the top of the dewatering machine's inner drum, with multiple sets of positioning screw holes distributed within the ring. Each set of positioning screw holes can be fitted with a corresponding pad. In actual use, one end of the fabric is inserted into the pad and pressed against the supporting top protrusion by a pressing head, thus limiting one end of the fabric. Under centrifugal force, a large amount of fabric, with one end restricted, reduces the likelihood of tangling caused by free movement and stacking, making it less prone to forming clumps and improving dewatering quality. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the structure of this utility model;

[0021] Figure 2 This is a cross-sectional view of the functional ring of the inner liner of this utility model;

[0022] Figure 3 This is a schematic diagram of the structure of the mating pad of this utility model;

[0023] Figure 4 This is a schematic diagram of the structure of the side groove of the pad plate of this utility model.

[0024] In the diagram: 1. Shock-absorbing support column; 2. Dehydrator outer shell; 3. Dehydrator inner liner; 4. Support column plate; 5. Closed top cover plate; 6. Drain pipe section; 7. Inner liner functional ring; 9. Positioning screw hole section; 10. Fitting pad; 11. Support top protrusion plate; 12. Pad main groove; 13. Pad side groove; 14. Pad support column; 15. Mounting pad; 16. Support top plate; 17. Clamping screw; 18. Clamping head; 19. Locking screw. Detailed Implementation

[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0026] Example

[0027] like Figure 1-4 As shown in the figure, an embodiment of this utility model proposes a shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing, including a dewatering machine shell 2 and a dewatering machine inner liner 3 disposed inside the dewatering machine shell 2. Shock-absorbing support columns 1 are installed outside the dewatering machine shell 2, distributed on the outer side. Each shock-absorbing support column 1 has a built-in shock-absorbing structure connected to the outer wall of the dewatering machine shell 2, providing a certain shock-absorbing and noise-reducing effect. The shock-absorbing structure adopts a known existing technical solution. Support column plates 4 are fixed to the side of the dewatering machine shell 2, and the top of the support column plates 4 is connected to a closed top cover plate 5 via a rotating shaft. In use, the closed top cover plate 5 is rotated and pressed onto the top of the dewatering machine outer shell 2. A certain gap is reserved between the dewatering machine inner liner 3 and the dewatering machine outer shell 2. This gap is used to discharge water from the drain pipe section 6. A drive mechanism is set at the bottom of the entire dewatering machine outer shell 2. The output of the drive mechanism passes through the dewatering machine outer shell 2 and is connected to the dewatering machine inner liner 3. It can drive the dewatering machine inner liner 3 to rotate inside the dewatering machine outer shell 2. In actual use, the fabric is put into the dewatering machine inner liner 3. The rotation of the dewatering machine inner liner 3 generates centrifugal force, so that the fabric gathered in the dewatering machine inner liner 3 is dewatered by centrifugal force.

[0028] An inner chamber functional ring 7 is integrally fixed to the top of the inner chamber 3 of the dehydrator. The inner wall of the inner chamber functional ring 7 has a beveled surface. Positioning screw holes 9 are arranged in a circular array on the surface of the beveled surface of the inner chamber functional ring 7. Each set of positioning screw holes 9 is a set of mounting points. A fitting pad 10 is attached to the surface of the inner chamber functional ring 7 at the positioning screw holes 9. The back of the fitting pad 10 adopts an arc surface design that matches the curvature of the inner chamber functional ring 7, making the fit between the fitting pad 10 and the inner chamber functional ring 7 more stable. A pad main groove 12 is formed on the surface of the fitting pad 10, making the groove shape of the pad main groove 12 V-shaped. A locking mechanism is provided on the inner side of the pad main groove 12, and the locking mechanism includes a pad side groove. 13. The mounting pad 15 and locking screw 19 are installed. The side groove 13 of the pad is located at the top of the main groove 12 of the pad. The mounting pad 15 fits into the groove of the side groove 13. The locking screw 19 passes longitudinally through the center of the mounting pad 15, and the center of the mounting pad 15 has a threaded hole that matches the thread of the locking screw 19. During actual assembly, the mounting pad 15 is placed in the groove of the side groove 13 of the pad, and the threaded hole at the center of the mounting pad 15 is aligned with one of the sets of positioning screw holes 9. Then, the locking screw 19 is inserted into the mounting pad 15, and the front end of the mounting pad 15 is threadedly connected to the positioning screw hole 9, thus positioning and installing the pad 10. The position of the positioning screw hole 9 is determined, and in order to limit one end of the fabric to the bonding pad 10, a clamping mechanism is also provided on the top of the bonding pad 10. The clamping mechanism includes a pad support column 14, a support top plate 16, a clamping screw 17, and a clamping head 18. The pad support column 14 is fixed to the top end of the bonding pad 10, and the support top plate 16 is fixed to the top of the pad support column 14. The clamping screw 17 is longitudinally inserted through the center of the support top plate 16, and the clamping head 18 is connected to the bottom of the clamping screw 17, so that the two sets of pad support columns 14 are distributed in a V-shape. In this way, there is a certain gap between the two sets of pad support columns 14, and the locking screw 19 is located in the middle of the two sets of pad support columns 14. The gap is designed to facilitate operation of the end of the locking screw 19. In actual operation, the pressing head 18 can be moved by the threaded connection between the pressing screw 17 and the supporting top plate 16. In order to improve the pressing head 18's ability to press the fabric onto the bonding pad 10, an upwardly protruding supporting top plate 11 is fixed at the bottom of the bonding pad 10. In actual operation, the end of the fabric is pressed by the pressing head 18 into the groove of the supporting top plate 11 and the surface of the bonding pad 10. The maximum extension of the pressing head 18 can reach the bonding pad 10 and the supporting top plate 11. The pressing head 18 is made of rubber to improve the pressing effect on the end of the fabric.

[0029] The threaded connections of the entire device can be mechanically locked by adding known spring washers (not shown in the diagram), which can reduce the impact of vibration on the threaded connections to a certain extent.

[0030] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing, comprising a dewatering machine outer shell (2) and a dewatering machine inner liner (3) disposed within the dewatering machine outer shell (2), characterized in that, Also includes: The inner liner functional ring (7) is fixed on the top of the inner liner (3) of the dehydrator, and the surface of the inner liner functional ring (7) is provided with positioning screw holes (9). The mating pad (10) is attached to the surface of the inner liner functional ring (7), and the surface of the mating pad (10) is provided with a main groove (12), the inner side of the main groove (12) is provided with a locking mechanism, and the top of the mating pad (10) is provided with a pressing mechanism.

2. The shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing according to claim 1, characterized in that: The positioning screw holes (9) are distributed in a ring at equal intervals on the inclined surface of the inner liner functional ring (7), and the back of the fitting pad (10) is fitted to the arc surface of the positioning screw holes (9).

3. The shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing according to claim 1, characterized in that: The locking mechanism includes a pad side groove (13), a mounting pad (15), and a locking screw (19). The pad side groove (13) is located at the top of the main groove (12) of the pad. The mounting pad (15) fits into the groove of the pad side groove (13). The locking screw (19) is longitudinally inserted through the center of the mounting pad (15).

4. The shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing according to claim 1, characterized in that: The main groove (12) of the pad is V-shaped, and the center of the mounting plate (15) is provided with a screw hole that is compatible with the thread of the locking screw (19).

5. The shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing according to claim 1, characterized in that: The clamping mechanism includes a pad support column (14), a support top plate (16), a clamping screw (17), and a clamping head (18). The pad support column (14) is fixed at the top end of the pad (10), and the support top plate (16) is fixed at the top of the pad support column (14). The clamping screw (17) is longitudinally inserted through the center of the support top plate (16), and the clamping head (18) is connected to the bottom of the clamping screw (17).

6. The shock-absorbing and noise-reducing dewatering machine for fabric printing and dyeing according to claim 5, characterized in that: The two sets of pad support columns (14) are V-shaped respectively, and the locking screw (19) is located in the middle gap of the two sets of pad support columns (14).

7. The shock-absorbing and noise-reducing dehydrator for fabric printing and dyeing according to claim 5, characterized in that: The bottom of the bonding pad (10) is fixed with an upwardly extending support top protrusion (11), and the maximum extension position of the pressing head (18) is located inside the support top protrusion (11).