A garment scrap recycling apparatus

By designing an automated compression and feeding system, the problems of low compression efficiency and safety hazards in garment scrap recycling equipment have been solved, achieving an efficient and safe scrap recycling process.

CN224410833UActive Publication Date: 2026-06-26SICHUAN SHENGSHAN BAIYULAN IND CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SICHUAN SHENGSHAN BAIYULAN IND CO LTD
Filing Date
2025-08-29
Publication Date
2026-06-26

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Abstract

The utility model relates to clothing processing technical field discloses a kind of clothing scrap recovery equipment, comprising: compression box, for loading scrap and providing compression space, including box, and be provided with inlet, discharge port on box;Compression part, including extrusion assembly, feed assembly, drive assembly;Discharging part, installation is in discharge port, including pusher assembly, valve assembly;Feed assembly pushes scrap into box, extrusion assembly compresses scrap, and then valve assembly opens, and pusher assembly pushes compressed scrap out of box. Through compression part and discharging part cooperation, so that discharging part and compression part between each other do not affect, can carry out discharging operation to scrap in compression cavity during the working of compression part, not only make overall operation speed greatly accelerate, simultaneously avoid artificial at inlet take compressed scrap, effectively prevent the safety accident caused by misoperation of extrusion assembly, avoid this security risk, guarantee worker safety.
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Description

Technical Field

[0001] This utility model relates to the field of garment processing technology, specifically, a garment scrap recycling device. Background Technology

[0002] Garment scraps refer to the waste materials generated during the cutting of fabric in the garment production process. These scraps are usually unusable parts due to limitations in the fabric's shape, design, and size. The generation of garment scraps is a common phenomenon in garment manufacturing, especially in mass production and complex designs, where scraps account for a relatively high proportion of raw materials. Although scraps are generally considered waste, their recycling and reuse are of great importance.

[0003] In recent years, with the increasing awareness of environmental protection, more and more garment manufacturers and related industries have begun to focus on the recycling of garment scraps. Through professional recycling equipment, scraps can be cut, compressed, washed, and sorted, and then transformed into recycled textiles, environmentally friendly products, industrial materials, etc., reducing resource waste and environmental pollution.

[0004] Existing scrap recycling equipment typically compresses and packages scraps to save space; however, most compression methods involve using a hydraulic cylinder to drive a pressure plate to compress the scraps in a container, and then workers remove them after compression. This method requires stopping the machine when workers remove the scraps, reducing compression efficiency; at the same time, if workers accidentally start the hydraulic cylinder while removing materials, it can cause safety accidents and pose safety hazards. Utility Model Content

[0005] The purpose of this invention is to provide a garment scrap recycling device that solves the problems of low compression efficiency and safety hazards in existing scrap recycling devices.

[0006] This utility model is achieved through the following technical solution: a garment scrap recycling device, comprising:

[0007] A compression box for loading scrap materials and providing compression space includes a box body, on which a feed inlet and a discharge outlet are provided, and a feed hopper is provided on the feed inlet;

[0008] The compression section is used to compress the scrap material in the compression box, and includes an extrusion assembly, a feeding assembly, and a drive assembly, wherein the drive assembly is used to drive the extrusion assembly and the feeding assembly.

[0009] The feeding section, installed at the discharge port, is used to discharge the compressed scrap material from the compression box, and includes a pushing assembly and a valve assembly;

[0010] The feeding assembly pushes the scrap material at the feed inlet into the box, the extrusion assembly compresses the scrap material, then the valve assembly opens, and the pushing assembly pushes the compressed scrap material out of the box.

[0011] To better realize this utility model, the pushing assembly further includes a support plate, a connecting rib, a feeding plate, and a first hydraulic cylinder. The support plate and the feeding plate are slidably connected to the housing. The support plate and the feeding plate are integrally formed. The connecting rib is installed on the support plate and the feeding plate. The first hydraulic cylinder is installed on the housing. A connecting rod is installed at the output end of the first hydraulic cylinder. The connecting rod is connected to the connecting rib.

[0012] To better realize this utility model, the valve assembly further includes a second hydraulic cylinder, a connecting plate, and a valve plate. The second hydraulic cylinder is mounted on the housing, and the connecting plate is mounted on the second hydraulic cylinder. The valve plate is mounted on the connecting plate and is slidably connected to the discharge port.

[0013] To better realize this utility model, the extrusion assembly further includes a compression plate, which is slidably connected to the housing. Multiple support legs are installed on the compression plate, and rollers are installed on the support legs. A baffle is installed on the compression plate, and the driving assembly drives the compression plate to move linearly back and forth.

[0014] To better realize this utility model, the drive assembly further includes a drive motor, a crank, and a first connecting rod. The drive motor is drivenly connected to the crank, the crank is rotatably connected to the first connecting rod, and the first connecting rod is rotatably connected to the compression plate.

[0015] To better realize this utility model, a worm gear is further installed at the output end of the drive motor, and a worm wheel is installed on the crank, with the worm gear meshing with the worm wheel.

[0016] To better realize this utility model, the feeding assembly further includes a support rod, a fifth connecting rod, and a sixth connecting rod. A second connecting rod and a third connecting rod are rotatably connected to the support rod. The second connecting rod and the third connecting rod are both rotatably connected to the sixth connecting rod. A pusher plate is installed at the end of the sixth connecting rod. A fourth connecting rod is fixedly connected to the third connecting rod. The fourth connecting rod is rotatably connected to the fifth connecting rod. The fifth connecting rod is rotatably connected to the compression plate.

[0017] Compared with the prior art, this utility model has the following advantages and beneficial effects: by setting the compression section and the feeding section to cooperate, the feeding section and the compression section do not affect each other. During the operation of the compression section, the scrap material in the compression chamber can be fed out. This not only greatly speeds up the overall operation, but also avoids the need for manual removal of compressed scrap material at the feed inlet. It effectively prevents safety accidents caused by the accidental start of the extrusion component, avoids this safety hazard, and ensures the safety of workers. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0019] Figure 2 This is a cross-sectional view of the overall structure of this utility model.

[0020] Figure 3 This is a schematic diagram of the compression section.

[0021] Figure 4 This is a schematic diagram of the material feeding section.

[0022] Wherein: 100-Compression box; 200-Compression section; 300-Discharge section; 101-Box body; 102-Feed hopper; 201-Push plate; 202-Compression plate; 203-Support leg; 204-Roller; 205-First connecting rod; 206-Second connecting rod; 207-Third connecting rod; 208-Support rod; 209-Fourth connecting rod; 210-Fifth connecting rod; 211-Sixth connecting rod; 212-Crank; 213-Drive motor; 214-Worm gear; 215-Worm wheel; 216-Baffle; 301-Support plate; 302-Connecting rib; 303-Discharge plate; 304-First hydraulic cylinder; 305-Connecting rod; 306-Second hydraulic cylinder; 307-Connecting plate; 308-Valve plate. Detailed Implementation

[0023] 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.

[0024] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0025] Example 1:

[0026] This embodiment provides a garment scrap recycling device, specifically as follows: Figures 1-2 As shown, it includes:

[0027] A compression box 100 is used to load scrap materials and provide compression space. It includes a box body 101, on which a feed inlet and a discharge outlet are provided. A feed hopper 102 is provided on the feed inlet.

[0028] The compression unit 200 is used to compress the scrap material in the compression box 100, and includes an extrusion assembly, a feeding assembly, and a drive assembly, wherein the drive assembly is used to drive the extrusion assembly and the feeding assembly.

[0029] The feeding section 300 is installed at the discharge port and is used to discharge the compressed scrap material from the compression box 100. It includes a pushing assembly and a valve assembly.

[0030] In use, workers throw messy scraps into the feed hopper 102. At this time, the drive component starts to drive the feed component, which pushes the scraps in the feed hopper 102 into the compression chamber in the housing 101. At the same time, the drive component also drives the extrusion component, which gradually extrudes the scraps in the compression chamber multiple times. After the extrusion is completed, the valve component opens the discharge port on the housing 101, and then the push component pushes the compressed scraps out of the discharge port, where they are packaged and collected by the workers.

[0031] With the above settings, the feeding section 300 and the compression section 200 do not interfere with each other. During the operation of the compression section 200, the scrap material in the compression chamber can be fed out. This not only greatly speeds up the overall operation, but also avoids the need for manual removal of compressed scrap material at the feed inlet. It effectively prevents safety accidents caused by the accidental start of the extrusion component, avoids this safety hazard, and ensures the safety of workers.

[0032] Example 2:

[0033] This embodiment further expands the feeding section 300 based on the above embodiment, specifically as follows: Figure 2 , Figure 4 As shown, the pushing assembly includes a support plate 301, a connecting rib 302, a feeding plate 303, and a first hydraulic cylinder 304. The support plate 301 and the feeding plate 303 are slidably connected to the housing 101. The support plate 301 and the feeding plate 303 are integrally formed. The connecting rib 302 is installed on the support plate 301 and the feeding plate 303. The first hydraulic cylinder 304 is installed on the housing 101. A connecting rod 305 is installed at the output end of the first hydraulic cylinder 304. The connecting rod 305 is connected to the connecting rib 302.

[0034] Furthermore, the valve assembly includes a second hydraulic cylinder 306, a connecting plate 307, and a valve plate 308. The second hydraulic cylinder 306 is mounted on the housing 101, the connecting plate 307 is mounted on the second hydraulic cylinder 306, the valve plate 308 is mounted on the connecting plate 307, and the valve plate 308 is slidably connected to the discharge port.

[0035] After the scrap material is compressed, the second hydraulic cylinder 306 is activated. When the second hydraulic cylinder 306 extends, it drives the connecting plate 307, which in turn drives the valve plate 308, thereby opening the discharge port. Then, the first hydraulic cylinder 304 is activated. When the first hydraulic cylinder 304 retracts, it simultaneously drives the connecting rod 305, which in turn causes the connecting rib 302 to drive the support plate 301 and the discharge plate 303 to press down. When the discharge plate 303 presses down, it presses down the compressed scrap material in the compression chamber and then discharges it from the discharge port. At the same time, the support plate 301 can separate the compression chamber, providing support for the compression operation of the compression section 200 at this time. After the scrap material is discharged, the second hydraulic cylinder 306 retracts and the first hydraulic cylinder 304 extends to complete the reset. The scrap material in the compression chamber is then pressed against the end of the box 101, and a new round of scrap material compression operation begins.

[0036] The other parts of this embodiment are the same as those in the above embodiments, and will not be described again.

[0037] Example 3:

[0038] This embodiment further expands the compression section 200 based on the above embodiment, specifically as follows: Figure 2 , Figure 3 As shown, the extrusion assembly includes a compression plate 202, which is slidably connected to the housing 101. Multiple support legs 203 are installed on the compression plate 202, and rollers 204 are installed on the support legs 203. A baffle 216 is installed on the compression plate 202. The drive assembly drives the compression plate 202 to move linearly back and forth.

[0039] Furthermore, the drive assembly includes a drive motor 213, a crank 212, and a first connecting rod 205. The drive motor 213 is connected to the crank 212 in a transmission manner, the crank 212 is rotatably connected to the first connecting rod 205, and the first connecting rod 205 is rotatably connected to the compression plate 202.

[0040] Furthermore, a worm gear 214 is installed at the output end of the drive motor 213, and a worm wheel 215 is installed on the crank 212. The worm gear 214 meshes with the worm wheel 215 to reduce speed and increase torque.

[0041] Furthermore, the feeding assembly includes a support rod 208, a fifth connecting rod 210, and a sixth connecting rod 211. A second connecting rod 206 and a third connecting rod 207 are rotatably connected to the support rod 208. The second connecting rod 206 and the third connecting rod 207 are both rotatably connected to the sixth connecting rod 211. A pusher plate 201 is installed at the end of the sixth connecting rod 211. A fourth connecting rod 209 is fixedly connected to the third connecting rod 207. The fourth connecting rod 209 is rotatably connected to the fifth connecting rod 210. The fifth connecting rod 210 is rotatably connected to the compression plate 202.

[0042] When the compression unit 200 is working, the power of the drive motor 213 is transmitted to the worm wheel 215 through the worm 214. The worm wheel 215 drives the crank 212, which in turn drives the first connecting rod 205. The first connecting rod 205 pushes the compression plate 202 to move linearly back and forth in the compression chamber. When the compression plate 202 moves, the roller 204 rolls in the compression chamber as a fulcrum. The end face of the compression plate 202 is used to compress the scrap material. The baffle 216 is to prevent some scrap material from falling to the other side of the compression plate 202. When the compression plate 202 moves, it synchronously drives the fifth link 210, which in turn pulls the fourth link 209 and the third link 207. At this time, under the combined action of the second link 206 and the third link 207, the sixth link 211 remains vertical and moves longitudinally along an arc trajectory. This allows the pusher plate 201 to continuously push the scrap material from the feed hopper 102 into the compression chamber, preventing the scrap material from clogging or getting stuck in the feed hopper 102. When the compression plate 202 retracts to the end of its stroke, the pusher plate 201 presses down to the end of its stroke; conversely, when the compression plate 202 extends to the end of its stroke, the pusher plate 201 moves upwards to the end of its stroke, ensuring there is no conflict.

[0043] The other parts of this embodiment are the same as those in the above embodiments, and will not be described again.

[0044] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Any simple modifications or equivalent changes made to the above embodiments based on the technical essence of the present utility model shall fall within the protection scope of the present utility model.

Claims

1. A garment scrap recycling device, characterized in that, include: A compression box (100) is used to load scrap materials and provide compression space, including a box body (101), on which a feed inlet and a discharge outlet are provided, and a feed hopper (102) is provided on the feed inlet. The compression unit (200) is used to compress the scrap in the compression box (100), and includes an extrusion assembly, a feeding assembly, and a driving assembly, wherein the driving assembly is used to drive the extrusion assembly and the feeding assembly; The unloading section (300), installed at the discharge port, is used to discharge the compressed scrap material from the compression box (100), and includes a pushing assembly and a valve assembly; The feeding assembly pushes the scrap material at the feed inlet into the box (101), the extrusion assembly compresses the scrap material, and then the valve assembly opens, and the pushing assembly pushes the compressed scrap material out of the box (101).

2. The garment scrap recycling equipment according to claim 1, characterized in that: The feeding assembly includes a support plate (301), a connecting rib (302), a feeding plate (303), and a first hydraulic cylinder (304). The support plate (301) and the feeding plate (303) are slidably connected to the housing (101). The support plate (301) and the feeding plate (303) are integrally formed. The connecting rib (302) is installed on the support plate (301) and the feeding plate (303). The first hydraulic cylinder (304) is installed on the housing (101). A connecting rod (305) is installed at the output end of the first hydraulic cylinder (304). The connecting rod (305) is connected to the connecting rib (302).

3. The garment scrap recycling equipment according to claim 2, characterized in that: The valve assembly includes a second hydraulic cylinder (306), a connecting plate (307), and a valve plate (308). The second hydraulic cylinder (306) is mounted on the housing (101), and the connecting plate (307) is mounted on the second hydraulic cylinder (306). The valve plate (308) is mounted on the connecting plate (307) and is slidably connected to the discharge port.

4. A garment scrap recycling device according to any one of claims 1-3, characterized in that: The extrusion assembly includes a compression plate (202) which is slidably connected to the housing (101). Multiple legs (203) are mounted on the compression plate (202), and rollers (204) are mounted on the legs (203). A baffle (216) is mounted on the compression plate (202). The drive assembly drives the compression plate (202) to move linearly back and forth.

5. The garment scrap recycling equipment according to claim 4, characterized in that: The drive assembly includes a drive motor (213), a crank (212), and a first connecting rod (205). The drive motor (213) is connected to the crank (212) in a transmission manner. The crank (212) is rotatably connected to the first connecting rod (205). The first connecting rod (205) is rotatably connected to the compression plate (202).

6. The garment scrap recycling equipment according to claim 5, characterized in that: The output end of the drive motor (213) is equipped with a worm (214), and a worm wheel (215) is installed on the crank (212). The worm (214) meshes with the worm wheel (215).

7. A garment scrap recycling device according to claim 4, characterized in that: The feeding assembly includes a support rod (208), a fifth connecting rod (210), and a sixth connecting rod (211). The support rod (208) is rotatably connected to a second connecting rod (206) and a third connecting rod (207). The second connecting rod (206) and the third connecting rod (207) are both rotatably connected to the sixth connecting rod (211). A pusher plate (201) is installed at the end of the sixth connecting rod (211). A fourth connecting rod (209) is fixedly connected to the third connecting rod (207). The fourth connecting rod (209) is rotatably connected to the fifth connecting rod (210). The fifth connecting rod (210) is rotatably connected to the compression plate (202).