A heavy metal material separation device for renewable resources

By designing a heavy metal material separation device that includes a separation box, a conveyor box, and a crushing box, and using a conveyor belt and motor drive to achieve continuous material flow and reagent spraying, the problem of heavy metals being difficult to separate from electroplating waste is solved, and the effective recovery of heavy metals and environmental protection are achieved.

CN224487131UActive Publication Date: 2026-07-14HEBEI HONGLEI RENEWABLE RESOURCES RECYCLING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HEBEI HONGLEI RENEWABLE RESOURCES RECYCLING CO LTD
Filing Date
2025-06-30
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing technologies are insufficient for effectively separating and recycling heavy metals from electroplating waste, leading to environmental pollution and resource waste.

Method used

Design a heavy metal material separation device including a separation box, a conveyor box, a crushing box and an electromagnetic plate. The device achieves continuous flow and separation of materials through a conveyor belt and a motor drive, and uses a nozzle to spray reagents to carry out heavy metal reactions, thereby achieving the separation of magnetic and non-magnetic materials.

Benefits of technology

It has achieved effective separation and recycling of heavy metals, reduced environmental pollution, and promoted the recycling of resources.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224487131U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of heavy metal material separation devices of renewable resources, including separation tank, the inside rotation of separation tank is equipped with two rotating rods C, the outer surface of two rotating rods C is commonly transmission installation and has conveyor belt C;The utility model is rotated by motor C and conveyor belt C rotation, to transport the material after crushing, this step ensures the continuous flow of material in the processing process, creates conditions for subsequent chemical treatment, by pump body and input pipeline extraction separation tank bottom reagent, by output pipeline and spray head respectively to magnetic material and non-magnetic material are sprayed, this step makes the heavy metal on the surface of material and reagent react, to realize the separation of heavy metal, can effectively separate and recover heavy metal material, reduce the pollution of heavy metal to environment, not only help to protect environment, but also recycle valuable heavy metal resources, promote the recycling of resources.
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Description

Technical Field

[0001] This utility model relates to the field of renewable resource technology, specifically to a heavy metal material separation device for renewable resources. Background Technology

[0002] Heavy metals in electroplating waste can also be regarded as valuable renewable resources. Through proper treatment and recycling, these heavy metals can be reused, which can not only solve environmental pollution problems, but also obtain considerable economic benefits. At the same time, with the increasing scarcity of global heavy metal resources, recycling heavy metal waste can also alleviate resource pressure to a certain extent. Therefore, we provide a heavy metal material separation device for renewable resources to solve the above problems. Utility Model Content

[0003] The purpose of this invention is to provide a heavy metal material separation device for renewable resources to solve the problems mentioned in the background art.

[0004] To achieve the above objectives, this utility model provides the following technical solution: a heavy metal material separation device for recycled resources, comprising a separation box, two rotating rods C rotatably mounted inside the separation box, a conveyor belt C jointly driven on the outer surfaces of the two rotating rods C, a motor C mounted on the outer surface of the separation box, the output end of the motor C penetrating the separation box and connected to the front end of one of the rotating rods C, a partition plate installed inside the separation box, multiple nozzles mounted on the outer surface of the partition plate, a discharge port opened on the outer surface of the separation box, a pump body mounted on the outer surface of the separation box, an input pipe connected to the input end of the pump body, the bottom end of the input pipe connected to the outer surface of the separation box, an output pipe connected to the output end of the pump body, the top end of the output pipe penetrating the separation box and connected to the outer surface of the multiple nozzles.

[0005] The upper surface of the separation box is equipped with a conveyor box, and a rotating rod A is rotatably installed inside the conveyor box. The outer surfaces of the two rotating rods A are connected to a conveyor belt A for transmission.

[0006] The outer surface of the conveyor box is equipped with a motor A, and the output end of the motor A passes through the conveyor box and is connected to the front end of one of the rotating rods A.

[0007] An auxiliary frame is installed on the outer surface of the conveyor box, and a fixed frame is installed inside the separation box. Two rotating rods B are rotatably installed inside the fixed frame, and the outer surfaces of the two rotating rods B are connected to a conveyor belt B for transmission.

[0008] The outer surface of the fixed frame is equipped with a motor B, the output end of which passes through the fixed frame and is connected to the left end of one of the rotating rods B. The outer surface of the conveyor belt B is equipped with multiple electromagnetic plates.

[0009] The upper surface of the conveyor box is equipped with a crushing box, inside which two crushing rollers are rotatably installed. A crushing motor is installed on the outer surface of the crushing box, and the output end of the crushing motor passes through the crushing box and is connected to the right end of one of the crushing rollers. A box cover is installed on the upper surface of the crushing box.

[0010] The discharge port has two auxiliary plates installed inside, the outer surface of the separation box has a controller installed, and the bottom of the separation box has four support legs installed.

[0011] Compared with the prior art, the beneficial effects of this utility model are:

[0012] This invention uses a motor C to drive a rotating rod C and a conveyor belt C to rotate, thereby transporting the pulverized material. This step ensures continuous material flow during processing, creating conditions for subsequent chemical treatment. A pump drives the input pipe to extract reagents from the bottom of the separation tank, and the reagents are sprayed onto magnetic and non-magnetic materials through the output pipe and nozzles. This step causes the heavy metals on the material surface to react with the reagents, thereby achieving the separation of heavy metals. This effectively separates and recycles heavy metal materials, reducing heavy metal pollution to the environment. This not only helps protect the environment but also recovers valuable heavy metal resources, promoting resource recycling. Attached Figure Description

[0013] Figure 1 This is a three-dimensional structural schematic diagram of a heavy metal material separation device for renewable resources according to the present invention;

[0014] Figure 2 This is a side view of a heavy metal material separation device for renewable resources according to the present invention.

[0015] Figure 3 This is a front sectional view of a heavy metal material separation device for renewable resources according to the present invention;

[0016] Figure 4 This is a rear cross-sectional view of a heavy metal material separation device for renewable resources according to this utility model.

[0017] In the picture:

[0018] 1. Separation box; 2. Support leg; 3. Controller; 4. Conveying box; 5. Crushing box; 6. Box cover; 7. Crushing motor; 8. Crushing roller; 9. Rotating rod A; 10. Conveyor belt A; 11. Fixing frame; 12. Rotating rod B; 13. Motor B; 14. Conveyor belt B; 15. Electromagnetic plate; 16. Auxiliary frame; 17. Rotating rod C; 18. Conveyor belt C; 19. Motor C; 20. Partition plate; 21. Nozzle; 22. Auxiliary plate; 23. Discharge port; 24. Pump body; 25. Input pipe; 26. Output pipe; 27. Motor A. Detailed Implementation

[0019] 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.

[0020] Please see Figure 1-4 This utility model provides a technical solution: a heavy metal material separation device for renewable resources, including a separation box 1. Two rotating rods C17 are rotatably installed inside the separation box 1. A conveyor belt C18 is driven by the outer surfaces of the two rotating rods C17. A motor C19 is installed on the outer surface of the separation box 1. The output end of the motor C19 passes through the separation box 1 and connects to the front end of one of the rotating rods C17. A partition 20 is installed inside the separation box 1. Multiple nozzles 21 are installed on the outer surface of the partition 20. A discharge port 23 is opened on the outer surface of the separation box 1. A pump body 24 is installed on the outer surface of the separation box 1. An input pipe 25 is connected to the input end of the pump body 24. The bottom end of the input pipe 25 is connected to the outer surface of the separation box 1. An output pipe 26 is connected to the output end of the pump body 24. The top end of the output pipe 26 passes through the separation box 1 and connects to the outer surface of the multiple nozzles 21.

[0021] Among them, a conveyor box 4 is installed on the upper surface of the separation box 1, and a rotating rod A9 is rotatably installed inside the conveyor box 4. The outer surfaces of the two rotating rods A9 are connected to the conveyor belt A10 for transmission.

[0022] Among them, a motor A27 is installed on the outer surface of the conveyor box 4, and the output end of the motor A27 passes through the conveyor box 4 and is connected to the front end of one of the rotating rods A9.

[0023] The outer surface of the conveyor box 4 is equipped with an auxiliary frame 16, and the inside of the separation box 1 is equipped with a fixed frame 11. Two rotating rods B12 are rotatably installed inside the fixed frame 11, and the outer surfaces of the two rotating rods B12 are connected to the conveyor belt B14 for transmission.

[0024] The outer surface of the fixed frame 11 is equipped with a motor B13. The output end of the motor B13 passes through the fixed frame 11 and is connected to the left end of one of the rotating rods B12. The outer surface of the conveyor belt B14 is equipped with multiple electromagnetic plates 15. The electromagnetic plates 15 can attract magnetic materials and separate them for easy subsequent processing.

[0025] The upper surface of the conveyor box 4 is equipped with a crushing box 5. Inside the crushing box 5, two crushing rollers 8 are rotatably installed. The outer surface of the crushing box 5 is equipped with a crushing motor 7. The output end of the crushing motor 7 passes through the crushing box 5 and is connected to the right end of one of the crushing rollers 8. The upper surface of the crushing box 5 is equipped with a box cover 6. The crushing motor 7 drives the crushing rollers 8 to crush the material inside the crushing box 5, which facilitates subsequent processing. The box cover 6 can prevent debris from splashing during the crushing process.

[0026] The discharge port 23 has two auxiliary plates 22 installed inside, the outer surface of the separation box 1 has a controller 3 installed, and the bottom surface of the separation box 1 has four support legs 2 installed.

[0027] Working Principle: In operation, the material to be processed is first poured into the crushing chamber 5. The crushing motor 7 is started via the controller 3, driving the crushing roller 8 to crush the material inside the crushing chamber 5. The crushed material falls onto the conveyor belt A10 inside the conveyor box 4. The motor A27 is started, driving the rotating rod A9 and the conveyor belt A10 to rotate, conveying the material on the conveyor belt A10. During the conveying process, the motor B13 is started, driving the rotating rod B12 and the conveyor belt B14 to rotate, which in turn drives the electromagnetic plate 15 on the conveyor belt B14 to move back and forth, starting the conveyor belt. The electromagnetic plate 15 above the conveyor belt 10 attracts the magnetic material in the material. The attracted magnetic material falls into the separation box 1 through the auxiliary frame 16. The remaining material continues to be conveyed to the separation box 1. Inside, the material falls onto conveyor belt C18, where it is separated from other materials by partition 20. Motor C19 drives rotating rod C17 and conveyor belt C18 to rotate, which in turn drives conveyor belt C18 to transport the material through discharge port 23 to the outside of separation box 1. During the transport process, pump body 24 is activated to drive input pipe 25 to extract reagent from the bottom of separation box 1. The reagent is then sprayed onto magnetic and non-magnetic materials through output pipe 26 and nozzle 21, causing the heavy metals on the surface of the materials to react. The reacting reagent permeates through the filter holes on conveyor belt C18 to the bottom of separation box 1. The reacted material is then transported to the outside of separation box 1, and the reacting reagent is finally discharged through the drain pipe of separation box 1, thus achieving effective separation and recovery of heavy metal materials.

[0028] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A heavy metal material separation device for recycling resources, comprising a separation tank (1), characterized in that: The inner part of the separation box (1) is rotatably provided with two rotating rods C (17), the outer surfaces of the two rotating rods C (17) are jointly and drivably provided with a conveying belt C (18), the outer surface of the separation box (1) is provided with a motor C (19), the output end of the motor C (19) penetrates through the separation box (1) and is connected with the front end of one of the rotating rods C (17), the inner part of the separation box (1) is provided with a partition plate (20), the outer surface of the partition plate (20) is provided with a plurality of nozzles (21), the outer surface of the separation box (1) is provided with a discharge port (23), the outer surface of the separation box (1) is provided with a pump body (24), the input end of the pump body (24) is communicated with an input pipeline (25), the bottom end of the input pipeline (25) is communicated with the outer surface of the separation box (1), the output end of the pump body (24) is communicated with an output pipeline (26), and the top end of the output pipeline (26) penetrates through the separation box (1) and is communicated with the outer surfaces of the nozzles (21).

2. The heavy metal material separation device for recycling resources according to claim 1, characterized in that: The upper surface of the separation box (1) is provided with a conveying box (4), and the inner part of the conveying box (4) is rotatably provided with rotating rods A (9).

3. The device for separating heavy metal materials from renewable resources according to claim 2, characterized in that: The outer surface of the conveying box (4) is provided with a motor A (27), and the output end of the motor A (27) penetrates through the conveying box (4) and is connected with the front end of one of the rotating rods A (9).

4. The device for separating heavy metal materials of renewable resources according to claim 3, characterized in that: The outer surface of the conveying box (4) is provided with an auxiliary frame (16), the inner part of the separation box (1) is provided with a fixing frame (11), the inner part of the fixing frame (11) is rotatably provided with two rotating rods B (12), and the outer surfaces of the two rotating rods B (12) are jointly and drivably connected with a conveying belt B (14).

5. The apparatus for separating heavy metal materials from renewable resources according to claim 4, wherein: The outer surface of the fixing frame (11) is provided with a motor B (13), and the output end of the motor B (13) penetrates through the fixing frame (11) and is connected with the left end of one of the rotating rods B (12). The outer surface of the conveying belt B (14) is provided with a plurality of electromagnetic plates (15).

6. The heavy metal material separation device for recycling resources according to claim 2, characterized in that: The upper surface of the conveying box (4) is provided with a crushing box (5), the inner part of the crushing box (5) is rotatably provided with two crushing rollers (8), the outer surface of the crushing box (5) is provided with a crushing motor (7), the output end of the crushing motor (7) penetrates through the crushing box (5) and is connected with the right end of one of the crushing rollers (8), and the upper surface of the crushing box (5) is provided with a box cover (6).

7. The heavy metal material separation device for recycling resources according to claim 1, characterized in that: The inner part of the discharge port (23) is provided with two auxiliary plates (22), the outer surface of the separation box (1) is provided with a controller (3), and the bottom surface of the separation box (1) is provided with four supporting legs (2).