Air conditioner heat insulation foam waste recycling equipment

By using a servo motor-driven screen cylinder and adhesive material in the foam recycling equipment, the problem of low efficiency in removing dust by water washing is solved, and a highly efficient and water-saving foam recycling process is achieved.

CN224405669UActive Publication Date: 2026-06-26宁波越微新材料科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
宁波越微新材料科技有限公司
Filing Date
2025-07-28
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Current foam recycling methods primarily rely on washing to remove dust, resulting in water waste and low efficiency.

Method used

It employs dust removal and collection components, utilizing a servo motor to drive a screen cylinder for centrifugal dust removal, combined with adhesive materials to absorb dust, thus avoiding the need for water washing.

Benefits of technology

It effectively removes dust from foam, saves water resources, improves recycling efficiency, and enhances the dust removal effect.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224405669U_ABST
    Figure CN224405669U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of air conditioner heat insulation bubble cotton waste recovery equipment, including dust removal cylinder, the side end surface of dust removal cylinder is equipped with fixed cylinder, the inside of fixed cylinder is equipped with servo motor, the inside of dust removal cylinder is welded with stabilizing cylinder at corresponding position of fixed cylinder, the inside of stabilizing cylinder is embedded with bearing, the inside of dust removal cylinder is welded with limit clamping block, the inside of limit clamping block is equipped with sliding slot, the transmission end of servo motor is connected with screen mesh cylinder, the side end surface of screen mesh cylinder is welded with sliding block, waste old air conditioner bubble cotton inside screen mesh cylinder will constantly impact each other, dust inside waste old bubble cotton will constantly impact and scatter at this time, then these dust will pass through screen mesh cylinder and drop to the inside of dust removal cylinder, dust can be preliminarily centrifuged and removed by screen mesh cylinder rotation centrifugation, without using water to soak and remove, not only save water source, and improve the recovery efficiency of bubble cotton.
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Description

Technical Field

[0001] This utility model relates to the field of foam technology, specifically to a waste recycling device for air conditioning insulation foam. Background Technology

[0002] Because of its high plasticity, foam has a certain recycling value. During the operation of an air conditioner, indoor air is constantly circulated through the air conditioning system. Foam is usually located inside the air conditioner and is used for functions such as heat insulation. When air flows through the foam, the dust particles it carries will adhere to the surface of the foam due to electrostatic adsorption or physical collision. For example, in an environment with poor air quality, the air contains a large number of dust, pollen, fiber and other tiny particles. After the air conditioner has been running for a long time, the foam will act like a "filter" and adsorb these impurities. Therefore, when recycling air conditioner foam, the dust in the foam needs to be removed.

[0003] However, most existing foam recycling processes use water washing to remove dust, which not only wastes a lot of water but also has low cleaning efficiency. To avoid the above-mentioned technical problems, it is necessary to provide an air conditioning insulation foam waste recycling device to overcome the defects in the existing technology. Utility Model Content

[0004] This utility model provides a waste recycling device for air conditioning insulation foam, which can effectively solve the problem mentioned in the background art that most existing foam recycling methods use water washing to remove dust, which not only wastes a lot of water but also has low cleaning efficiency.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a waste recycling device for air conditioning insulation foam, including a dust collection cylinder, wherein a dust collection component is installed on the inner side of the dust collection cylinder;

[0006] The dust removal assembly includes a fixed cylinder, a servo motor, a stabilizing cylinder, bearings, a limit block, a sliding groove, a screen cylinder, a sliding block, a discharge chute, a rotating hinge, a sealing plate, a magnet, and a bracket.

[0007] A fixed cylinder is installed on one end face of the dust collector cylinder, a servo motor is installed on the inner side of the fixed cylinder, a stabilizing cylinder is welded on the inner side of the dust collector cylinder at the corresponding position of the fixed cylinder, a bearing is embedded in the inner side of the stabilizing cylinder, a limit block is welded on the inner side of the dust collector cylinder, and a sliding groove is opened on the inner side of the limit block.

[0008] The servo motor is connected to a screen cylinder at its drive end. A sliding block is welded to one end face of the screen cylinder. A discharge chute is provided at the bottom of the outer side of the dust collector cylinder. A rotating hinge is welded to the outer side of the dust collector cylinder. A sealing plate is welded to the rotating end of the rotating hinge. A magnet is installed on the front of the dust collector cylinder. A bracket is welded to the bottom of the dust collector cylinder.

[0009] Preferably, a transmission groove is provided on the back of the dust collector at the position of the servo motor drive shaft, and one end face of the screen cylinder is welded to the drive shaft of the servo motor through the transmission groove.

[0010] Preferably, several limiting blocks are welded together, and the several limiting blocks are welded at equal angles to the inner side of the dust collector cylinder. The sliding block is slidably connected to the limiting blocks through a sliding groove.

[0011] Preferably, the inner diameter of the dust collector cylinder is 1.5 times the outer diameter of the screen cylinder, and the input end of the servo motor is electrically connected to the output end of the external power supply.

[0012] Preferably, a collection assembly is installed at the bottom outer side of the dust collection cylinder;

[0013] The collection assembly includes a discharge trough plate, a snap-fit ​​trough plate, snap-fit ​​posts, a waste box, adhesive, and a handle;

[0014] A discharge trough plate is welded to the outer side of the dust collector corresponding to the discharge trough. A snap-fit ​​trough plate is welded to one end face of the discharge trough plate. A snap-fit ​​post is embedded in the snap-fit ​​trough plate. A waste box is welded to one end face of the snap-fit ​​post. An adhesive is bonded to the bottom inner side of the waste box. A handle is welded to one end face of the waste box.

[0015] Preferably, there are two snap-fit ​​slot plates, which are symmetrically welded to the two end faces of the snap-fit ​​slot plate.

[0016] Compared with the prior art, the advantages of this utility model are: the structure of this utility model is scientific and reasonable, and it is safe and convenient to use.

[0017] 1. Equipped with a dust removal component, the waste air conditioning foam inside the screen cylinder will continuously collide with each other. At this time, the dust inside the waste foam will be continuously collided and scattered. Then, this dust will pass through the screen cylinder and fall into the dust removal cylinder. The dust can be initially removed by centrifugation through the rotation of the screen cylinder, without the need to use water for soaking and removal. This not only saves water resources but also improves the recycling efficiency of foam.

[0018] 2. Equipped with a collection component, dust will fall onto the adhesive surface and be adhered to, thus preventing it from being stirred up again during subsequent dust removal. After a period of use, the waste box can be removed from the outside of the discharge tray plate using the handle. At this time, the snap-fit ​​post will be removed from the inside of the snap-fit ​​tray plate, and the adhesive can then be replaced, further ensuring the efficiency of dust adhesion. Attached Figure Description

[0019] The accompanying drawings are provided to further understand the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention and do not constitute a limitation thereof.

[0020] In the attached diagram:

[0021] Figure 1 This is a schematic diagram of the structure of this utility model;

[0022] Figure 2 This is a schematic diagram of the structure of the dust removal component of this utility model;

[0023] Figure 3 This is a schematic diagram of the installation structure of the limiting block of this utility model;

[0024] Figure 4 This is a schematic diagram of the structure of the collection component of this utility model;

[0025] Labels in the diagram: 1. Dust collector cylinder;

[0026] 2. Dust removal components; 201. Fixed cylinder; 202. Servo motor; 203. Stabilizing cylinder; 204. Bearing; 205. Limiting block; 206. Sliding groove; 207. Screen cylinder; 208. Sliding block; 209. Discharge chute; 210. Rotating hinge; 211. Sealing plate; 212. Magnet; 213. Support;

[0027] 3. Collection components; 301. Discharge chute plate; 302. Snap-fit ​​chute plate; 303. Snap-fit ​​post; 304. Waste box; 305. Adhesive; 306. Handle. Detailed Implementation

[0028] The preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the preferred embodiments described herein are for illustration and explanation only and are not intended to limit the present invention.

[0029] Example: Figure 1-4 As shown, this utility model provides a technical solution: a waste recycling device for air conditioning insulation foam, including a dust collection cylinder 1, and a dust collection component 2 installed on the inner side of the dust collection cylinder 1.

[0030] The dust removal assembly 2 includes a fixed cylinder 201, a servo motor 202, a stabilizing cylinder 203, a bearing 204, a limit block 205, a sliding groove 206, a screen cylinder 207, a sliding block 208, a discharge chute 209, a rotating hinge 210, a sealing plate 211, a magnet 212, and a bracket 213.

[0031] A fixed cylinder 201 is installed on one end face of the dust collector 1. A servo motor 202 is installed on the inner side of the fixed cylinder 201. A stabilizing cylinder 203 is welded to the inner side of the dust collector 1 at the corresponding position of the fixed cylinder 201. A bearing 204 is embedded in the inner side of the stabilizing cylinder 203. A limit block 205 is welded to the inner side of the dust collector 1. A sliding groove 206 is opened on the inner side of the limit block 205.

[0032] The drive end of the servo motor 202 is connected to a screen cylinder 207. A transmission groove is provided on the back of the dust collector 1 at the position of the drive shaft of the servo motor 202. One end face of the screen cylinder 207 is welded to the drive shaft of the servo motor 202 through the transmission groove to facilitate the rotation of the screen cylinder 207. The inner diameter of the dust collector 1 is 1.5 times the outer diameter of the screen cylinder 207. The input end of the servo motor 202 is electrically connected to the output end of an external power supply for dust removal. A sliding block 208 and a limit lock are welded to one end face of the screen cylinder 207. Several limit blocks 205 are welded to the inner side of the dust collector cylinder 1 at equal angles. The sliding block 208 is slidably connected to the limit block 205 through the sliding groove 206, which is conducive to the stable rotation of the screen cylinder 207. A discharge chute 209 is provided at the bottom of the outer side of the dust collector cylinder 1. A rotating hinge 210 is welded to the outer side of the dust collector cylinder 1. A sealing plate 211 is welded to the rotating end of the rotating hinge 210. A magnet 212 is installed on the front of the dust collector cylinder 1. A bracket 213 is welded to the bottom of the dust collector cylinder 1.

[0033] A collection component 3 is installed on the bottom outer side of the dust collector 1;

[0034] The collection component 3 includes a discharge trough plate 301, a snap-fit ​​trough plate 302, a snap-fit ​​post 303, a waste box 304, an adhesive 305, and a handle 306;

[0035] A discharge trough plate 301 is welded to the outer side of the dust collector 1 at the position corresponding to the discharge trough 209. A snap-fit ​​trough plate 302 is welded to one end face of the discharge trough plate 301. A snap-fit ​​post 303 is embedded in the snap-fit ​​trough plate 302. A waste box 304 is welded to one end face of the snap-fit ​​post 303. There are two snap-fit ​​trough plates 302. The two snap-fit ​​trough plates 302 are symmetrically welded to the two end faces of the snap-fit ​​trough plate 302 to facilitate quick disassembly of the waste box 304. An adhesive 305 is bonded to the bottom inner side of the waste box 304. A handle 306 is welded to one end face of the waste box 304.

[0036] The working principle and usage process of this utility model are as follows: First, the operator puts the recycled waste foam into the inner side of the dust collector cylinder 1, thereby placing the waste foam into the inner side of the screen cylinder 207. After a certain amount of waste air conditioning foam has been placed into the inner side of the screen cylinder 207, the sealing plate 211 is closed, thereby attracting the sealing plate 211 to one side of the magnet 212. Then, the servo motor 202 inside the fixed cylinder 201 is turned on, thereby driving the screen cylinder 207 to rotate. At this time, the sliding block 208 on one side of the screen cylinder 207 will rotate in the sliding groove 206 inside the limit block 205. The screen cylinder 207 rotates stably inside the dust collector 1, causing the waste air conditioning foam inside the screen cylinder 207 to collide with each other. At this time, the dust inside the waste foam will be continuously scattered by the collision. Then, this dust will pass through the screen cylinder 207 and fall into the dust collector 1. The dust can be initially removed by centrifugal centrifugation through the rotation of the screen cylinder 207, without the need to soak it in water. This not only saves water but also improves the recycling efficiency of the foam. After the dust is initially removed, subsequent recycling processes can be carried out to improve work efficiency.

[0037] Next, after the dust centrifuges touches the inner wall of the dust collector 1, the dust will slide down the dust collector 1 to the discharge trough 209. Then, the dust will fall from the discharge trough plate 301 to the inside of the waste box 304. At this time, the dust will fall onto the surface of the adhesive 305 and be adhered by the adhesive 305, thus preventing it from being stirred up again in subsequent dust removal and further improving the dust removal efficiency. After a period of use, the waste box 304 can be removed from the outside of the discharge trough plate 301 by the handle 306. At this time, the snap-fit ​​post 303 will be removed from the inside of the snap-fit ​​plate 302, and then the adhesive 305 can be replaced to further ensure the dust adhesion efficiency.

[0038] 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 waste recycling device for air conditioning insulation foam, comprising a dust collector (1), characterized in that: A dust removal assembly (2) is installed on the inner side of the dust removal cylinder (1); The dust removal assembly (2) includes a fixed cylinder (201), a servo motor (202), a stabilizing cylinder (203), a bearing (204), a limiting block (205), a sliding groove (206), a screen cylinder (207), a sliding block (208), a discharge chute (209), a rotating hinge (210), a sealing plate (211), a magnet (212), and a bracket (213); A fixed cylinder (201) is installed on one end face of the dust removal cylinder (1). A servo motor (202) is installed on the inner side of the fixed cylinder (201). A stabilizing cylinder (203) is welded to the inner side of the dust removal cylinder (1) at the position corresponding to the fixed cylinder (201). A bearing (204) is embedded in the inner side of the stabilizing cylinder (203). A limit block (205) is welded to the inner side of the dust removal cylinder (1). A sliding groove (206) is opened on the inner side of the limit block (205). The transmission end of the servo motor (202) is connected to a screen cylinder (207). A sliding block (208) is welded to one side end face of the screen cylinder (207). A discharge chute (209) is provided at the bottom of the outer side of the dust collector (1). A rotating hinge (210) is welded to the outer side of the dust collector (1). A sealing plate (211) is welded to the rotating end of the rotating hinge (210). A magnet (212) is installed on the front side of the dust collector (1). A bracket (213) is welded to the bottom of the dust collector (1).

2. The air conditioning insulation foam waste recycling equipment according to claim 1, characterized in that: A transmission groove is provided on the back of the dust collector (1) at the position of the transmission shaft of the servo motor (202), and one end face of the screen cylinder (207) is welded to the transmission shaft of the servo motor (202) through the transmission groove.

3. The air conditioning insulation foam waste recycling equipment according to claim 1, characterized in that: The limiting block (205) is welded in several parts, and the limiting block (205) is welded at equal angles to the inner side of the dust collector (1). The sliding block (208) is slidably connected to the limiting block (205) through the sliding groove (206).

4. The air conditioning insulation foam waste recycling equipment according to claim 1, characterized in that: The inner diameter of the dust collector (1) is 1.5 times the outer diameter of the screen cylinder (207), and the input end of the servo motor (202) is electrically connected to the output end of the external power supply.

5. The air conditioning insulation foam waste recycling equipment according to claim 1, characterized in that: A collection assembly (3) is installed on the bottom outer side of the dust collector (1); The collection component (3) includes a discharge trough plate (301), a snap-fit ​​trough plate (302), a snap-fit ​​post (303), a waste box (304), an adhesive (305), and a handle (306); A discharge trough plate (301) is welded to the outer side of the dust collector (1) at the position corresponding to the discharge trough (209). A snap-fit ​​trough plate (302) is welded to one side end face of the discharge trough plate (301). A snap-fit ​​post (303) is embedded in the snap-fit ​​trough plate (302). A waste box (304) is welded to one side end face of the snap-fit ​​post (303). An adhesive (305) is bonded to the bottom inner side of the waste box (304). A handle (306) is welded to one side end face of the waste box (304).

6. The air conditioning insulation foam waste recycling equipment according to claim 5, characterized in that: Two snap-fit ​​slot plates (302) are provided, and the two snap-fit ​​slot plates (302) are symmetrically welded to the two end faces of the snap-fit ​​slot plate (302).