A cleaning device for electrolytic copper powder
By designing an automated electrolytic copper powder cleaning device, which uses a motor to drive the screening cylinder and stirring rod for automated cleaning, the problem of low efficiency in manual cleaning in existing technologies is solved, and a highly efficient and uniform cleaning effect is achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGXI YIXIN COPPER MATERIALS CO LTD
- Filing Date
- 2025-07-16
- Publication Date
- 2026-07-03
AI Technical Summary
Existing methods for cleaning electrolytic copper powder rely on manual operation, resulting in low efficiency, high labor intensity, and uneven cleaning.
An electrolytic copper powder cleaning device was designed, comprising a main housing, a filter cylinder, a screening cylinder, and a stirring rod. The main rod is driven by a motor to rotate the screening cylinder, and the stirring rod and brushes perform automated cleaning. The inclined liquid outlet and solenoid valve enable automatic discharge.
It achieves efficient and uniform cleaning of electrolytic copper powder, reduces manual labor intensity, improves cleaning efficiency, and avoids problems such as raw material blockage and uneven screening.
Smart Images

Figure CN224443946U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of electrolytic copper powder processing equipment, and in particular to a cleaning device for electrolytic copper powder. Background Technology
[0002] Electrolytic copper powder: It has a uniform light rose-red appearance and must not contain foreign inclusions or lumps. Electrolytic copper powder produced by sulfuric acid solution electrolysis is widely used in powder metallurgy.
[0003] In the production process of electrolytic copper powder, the electrolytic copper powder processed in the previous step often needs to be put into a special washing tank for washing. The current common washing method is to pour it into the washing drum, then manually stir it with iron rods and then filter it. This method is labor-intensive, greatly increases the intensity of manual labor, and the stirring and washing are uneven and inefficient.
[0004] Therefore, a cleaning device for electrolytic copper powder is proposed. Utility Model Content
[0005] (a) Technical problems to be solved
[0006] To overcome the shortcomings of existing technologies, a cleaning device for electrolytic copper powder is proposed to solve the problems of low efficiency, high labor consumption, high labor intensity, and low work efficiency caused by the current manual cleaning of electrolytic copper powder.
[0007] (II) Technical Solution
[0008] This utility model is achieved through the following technical solution: This utility model proposes a cleaning device for electrolytic copper powder, including a main box with an opening at the top, and a detachable box cover installed at the top opening. A feed inlet is installed on the top side of the box cover.
[0009] The main housing is equipped with a funnel-shaped filter screen cylinder, and the bottom end of the filter screen cylinder is provided with a discharge port that penetrates the bottom of the main housing. A solenoid valve is installed inside the discharge port.
[0010] The filter cylinder has an open-top screening cylinder installed inside. The screening cylinder has a main rod in the middle, and the top of the main rod is connected to the box cover through a bearing. The top of the box cover is equipped with a motor connected to the main rod. Several stirring rods are installed on the outside of the screening cylinder.
[0011] Furthermore, the outer side of the screening cylinder is symmetrically provided with force-bearing plates, and the outer side of the force-bearing plates is located in contact with the inner side of the brush and the filter cylinder.
[0012] Furthermore, the main housing has a liquid inlet on one side of its bottom end, the bottom end of the main housing is tilted to one side, and the tilted bottom end has a liquid outlet that penetrates the main housing.
[0013] Furthermore, the bottom of the screening cylinder is provided with a ring of inwardly inclined receiving plates, and the feed inlet is located inside the receiving plates.
[0014] Furthermore, a connecting block is provided on the outside of the filter cylinder to connect with the main housing, and a connecting rod is installed on the outside of the main rod to connect with the screening cylinder.
[0015] Furthermore, a support foot is added to the bottom end of the main housing, and a controller is installed on the outer side of the main housing.
[0016] Furthermore, handles are symmetrically installed on the outer side of the top surface of the box lid.
[0017] (III) Beneficial Effects
[0018] Compared with the prior art, this utility model has the following advantages:
[0019] 1. In this utility model, electrolytic copper powder raw material is poured into the screening cylinder through the feed port. The raw material is screened by the rotation driven by the main rod. This allows large pieces of raw material in the screening cylinder to be screened out, thereby avoiding the presence of large particles in the raw material, which would affect the quality of the raw material. This makes the material more practical, produces better results, reduces the subsequent screening rate, and improves the working efficiency.
[0020] 2. In this utility model, the rotation of the screening screen cylinder driven by the motor causes the outer stirring rod to stir the electrolytic copper powder raw material inside the filter screen cylinder. This process cleans the raw material during the turning process, avoiding the low efficiency and high labor intensity of manual turning and washing. This results in better and more uniform cleaning, and faster work efficiency.
[0021] 3. In this utility model, a brush is set on the outside of the force plate to brush the inside of the filter cylinder, which can avoid the raw material clogging the filter cylinder and thus the effect of continuous filtration is not good, thereby making the working effect better. Attached Figure Description
[0022] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:
[0023] Figure 1 This is a schematic diagram of the structure of this utility model;
[0024] Figure 2 This is a schematic diagram of the internal structure of the present invention;
[0025] Figure 3 This is a top view of the internal structure of this utility model;
[0026] In the diagram: Main body-1, Support leg-2, Controller-3, Cover-4, Liquid inlet-5, Feed inlet-6, Handle-7, Motor-8, Filter screen-9, Connecting block-10, Discharge port-11, Solenoid valve-12, Screening screen-13, Main rod-14, Connecting rod-15, Force plate-16, Brush-17, Support plate-18, Liquid outlet-19, Stirring rod-110. Detailed Implementation
[0027] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain this utility model and are not intended to limit this utility model.
[0028] Please see Figure 1 , Figure 2 and Figure 3 This utility model provides a cleaning device for electrolytic copper powder, including a main housing 1 with an opening at the top for easy access and cleaning. A liquid inlet 5 is located on one side of the bottom of the main housing 1 to allow cleaning fluid to be introduced and used to clean the electrolytic copper powder inside. The bottom of the main housing 1 is tilted to one side to facilitate downward discharge and prevent accumulation on one side. A liquid outlet 19 is located at the tilted bottom, penetrating the main housing 1 to allow the cleaned liquid to drain out. The liquid can enter and exit from one side simultaneously, resulting in better cleaning effect. Support feet 2 are added to the bottom of the main housing 1 to raise its height and facilitate the discharge of the cleaned material from the bottom. The main housing 1 has an outer... A controller 3 is installed on the side, which allows the staff to operate the electrical components in the device through the externally purchased controller 3, making it more convenient for the staff to use. A detachable box cover 4 is installed at the top opening, so that the top of the main box 1 can be opened to clean the inside, preventing the inside from becoming blocked after long-term use, making cleaning easier and making it easier for the staff to replace the internal items, saving more time. A handle 7 is symmetrically installed on the outer side of the top surface of the box cover 4, so that the staff can lift the box cover 4 upwards with force. A feed port 6 is installed on the top side of the box cover 4 for material unloading. Two ports can be set symmetrically to make the unloading effect better.
[0029] The main housing 1 is equipped with a funnel-shaped filter cylinder 9. The funnel shape facilitates downward material discharge from the bottom. The filter cylinder 9 facilitates the filtration of electrolytic copper powder. The filter cylinder is designed with a funnel shape to facilitate the filtration and discharge. The filter cylinder 9 is equipped with a connecting block 10 on the outside to connect with the main housing 1, which improves the stability of the filter cylinder 9 and the main housing 1. The bottom of the filter cylinder 9 is provided with a discharge port 11 that penetrates the bottom of the main housing 1 to discharge the cleaned electrolytic copper powder downward. The discharge port 11 is equipped with a solenoid valve 12, which allows the operator to start the discharge. The discharge time can be automatically selected after cleaning, resulting in better discharge effect.
[0030] The filter cylinder 9 has an internal screening cylinder 13 with an open top. The screening cylinder 13 is made of screening mesh with relatively large internal mesh size for easy material feeding. Positioned at the top of the filter cylinder 9, it prevents electrolytic copper powder from returning during cleaning. A ring of inwardly inclined receiving plates 18 is located at the bottom of the screening cylinder 13, with the feed inlet 6 inside the receiving plates 18. This facilitates the input of raw materials into the screening cylinder 13 for better screening and prevents direct entry into the filter cylinder 9. A gap exists between the top of the receiving plates 18 and the cover 4 to allow large particles to be discharged during cleaning. A main rod 14 is located in the middle of the screening cylinder 13, with connecting rods 15 attached to its outer side. The connecting rods 15 enhance stability and allow for force distribution on the raw materials during rotation. The top of the main rod 14 is connected to a shaft. The screen is connected to the cover 4, and a motor 8 is installed at the top of the cover 4 and connected to the main rod 14. Under the action of the motor 8, the main rod 14 drives the screening cylinder 13 to rotate, making the raw material screening rate faster during rotation. Several stirring rods 110 are installed on the outside of the screening cylinder 13, and the stirring rods 110 are connected to each other. This makes the rotation and washing of the raw materials inside the screen better when the screening cylinder 13 drives the stirring rods 110 to rotate, making the washing more thorough and avoiding manual cleaning, reducing labor intensity and increasing work efficiency. The screen cylinder 13 is symmetrically provided with force plates 16 on the outside, and the force plates 16 can also be connected to the outside of the stirring rods 110 for easier force application. The outside of the force plates 16 is located in contact with the brush 17 and the inside of the filter cylinder 9. This allows the brush 17 to clean the raw materials attached to the inside of the filter cylinder 9, avoiding clogging and affecting the filtration effect, thus increasing work efficiency.
[0031] Working principle: In use, first connect the motor 8, solenoid valve 12 and controller 3, and connect them to an external power supply. Then, feed the raw material into the main box 1 through the feed port 6. The raw material is fed into the screening cylinder 13 through the receiving plate 18. The motor 8 drives the main rod 14 to rotate the screening cylinder 13, which filters the raw material into the filter cylinder 9. Under the action of the liquid inlet 5, cleaning liquid can be introduced into the internal part. The screening cylinder 13 drives the stirring rod 110 to wash the raw material. After washing, the liquid outlet 19 is opened to discharge the liquid. Then, the solenoid valve 12 can be opened to discharge the raw material. When it is necessary to clean the inside, the lid 4 can be lifted and flipped up by the handle 7 to discharge the particles inside the screening cylinder 13 downwards. This completes the work.
[0032] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A cleaning device for electrolytic copper powder, comprising a main box (1) provided with an open upper end, and a detachable box cover (4) installed at the open upper end, a feed inlet (6) being installed on the top end side of the box cover (4), Its characteristics are: The main box (1) is equipped with a funnel-shaped filter cylinder (9), and the bottom end of the filter cylinder (9) is provided with a discharge port (11) that penetrates the bottom of the main box (1). A solenoid valve (12) is installed inside the discharge port (11). The filter cylinder (9) is equipped with a screening cylinder (13) with an open top. The screening cylinder (13) has a main rod (14) in the middle, and the top of the main rod (14) is connected to the box cover (4) through a bearing. The top of the box cover (4) is equipped with a motor (8) connected to the main rod (14). Several stirring rods (110) are installed on the outside of the screening cylinder (13).
2. The electrolytic copper powder cleaning device according to claim 1, characterized in that: The screening cylinder (13) is symmetrically provided with a force plate (16) on the outside, and the outside of the force plate (16) is located in contact with the brush (17) and the inner side of the filter cylinder (9).
3. The electrolytic copper powder cleaning apparatus of claim 1, wherein: The main box (1) has a liquid inlet (5) on one side of its bottom end. The bottom end of the main box (1) is tilted to one side, and the tilted bottom end has a liquid outlet (19) that penetrates the main box (1).
4. The electrolytic copper powder cleaning apparatus of claim 1, wherein: The bottom of the screening cylinder (13) is provided with a ring of inwardly inclined receiving plate (18), and the feed inlet (6) is located inside the receiving plate (18).
5. The electrolytic copper powder cleaning apparatus of claim 1, wherein: The filter cylinder (9) has a connecting block (10) on its outer side that connects to the main box (1), and the main rod (14) has a connecting rod (15) on its outer side that connects to the screening cylinder (13).
6. The electrolytic copper powder cleaning apparatus of claim 1, wherein: The bottom end of the main housing (1) is provided with a support foot (2), and a controller (3) is installed on the outer side of the main housing (1).
7. The electrolytic copper powder cleaning apparatus of claim 1, wherein: The top surface of the box cover (4) is symmetrically equipped with handles (7).