Cam plate anti-abrasion line machining structure

By combining the spiral grinding bracket and the drive cylinder, the problem of low grinding efficiency of cam plates in vibratory mills is solved, realizing efficient batch grinding and impurity filtration of cam plates, thus improving the quality of cam plates and the working environment.

CN224464417UActive Publication Date: 2026-07-07

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Filing Date
2025-08-03
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing vibratory mills, due to structural limitations, can only grind the same batch of cams at a time when grinding cams, resulting in low grinding efficiency for multiple batches of cams.

Method used

The combined structure of spiral grinding bracket and drive cylinder allows the abrasive balls and cam plates to collide and rub against each other during rotation. Different batches of cam plates are added and separated in batches through an isolation grinding box. Combined with impurity filter screen and sound insulation pad, the grinding efficiency and environmental friendliness are improved.

Benefits of technology

This technology enables efficient grinding of different batches of cam plates, ensuring consistent grinding results, improving the quality and production efficiency of cam plates, while reducing noise pollution and providing a better working environment.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of cam piece anti-abrasion line processing structures, it is related to cam piece polishing technical field, including mounting plate, its welding installation is in the both sides of the isolated polishing box, the device is rotated by installing spiral polishing support to make it cooperate driving cylinder, and then can make the abrasive small ball inside spiral polishing support and cam piece when spiral polishing support rotates, mutually collide and rub, and then make abrasive small ball to cam piece and polish, improve cam piece quality, spiral polishing support is when polishing to cam piece, staff can be added to the inside spiral polishing support in batches in batches different batches of cam piece, and then make device can polish to different batches of cam plate, and different batches of cam piece when being added to the inside spiral polishing support, different batches of cam piece cannot be mixed, improve cam piece polishing efficiency, and then ensure that the polishing effect of different batches of cam piece is consistent when discharging device.
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Description

Technical Field

[0001] This utility model relates to the field of cam plate grinding technology, specifically a cam plate anti-wear cutting structure. Background Technology

[0002] Cam plates are key components of cam mechanisms, typically mounted on a rotating shaft. They control the movement of mating parts by changing their own shape, achieving specific mechanical actions or control functions. They are generally disc-shaped or block-shaped, with different contour curves and shapes. Their surfaces are usually precision-machined to ensure good fit with other components and precise motion control. Some cam plates may also have special structures such as protrusions, grooves, or teeth to meet different working requirements. To ensure the quality of the cam plate's outer surface, workers need to use a vibratory grinder to polish it. Vibratory grinders do not produce grinding lines when polishing cam plates. During polishing, the cam plate and small abrasive particles are placed together in the vibratory grinder. The vibration of the grinder causes the cam plate and the small abrasive particles to rub against each other, thereby removing burrs from the cam plate's exterior.

[0003] However, existing vibratory mills can only grind cams in batches at a time due to their structure. Only after the grinding of one batch of cams is completed and the ground cams are removed can the next batch of cams be ground. This results in low grinding efficiency when grinding multiple batches of cams, and cams are usually placed together for grinding. Therefore, this does not meet the current requirements. To address this, we propose a cam anti-wear cutting machining structure. Utility Model Content

[0004] The purpose of this utility model is to provide a cam plate anti-wear cutting structure to solve the problem mentioned in the background art that when a vibratory mill grinds cam plates, the vibratory mill can only grind cam plates in batches once due to structural limitations. Only after the grinding of the same batch of cam plates is completed and the ground cam plates are removed can the next batch of cam plates be ground, resulting in low grinding efficiency when grinding multiple batches of cam plates.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a cam plate anti-wear cutting machining structure, including an isolation grinding box:

[0006] Mounting plates are welded to both sides of the isolation grinding box. There are two mounting plates, and a drive cylinder is rotatably mounted between the two mounting plates via a bearing. A spiral grinding bracket is fixedly mounted on the outside of the drive cylinder, and the spiral grinding bracket is configured with a mesh structure on the outside.

[0007] A waste discharge trough is located at the lower end of the isolation grinding box. An impurity filter screen is installed inside the waste discharge trough and is fixedly connected to the isolation grinding box. A material discharge trough is provided on one side of the lower end face of the isolation grinding box.

[0008] Preferably, a drive motor is provided on one side of the isolation grinding box, the drive motor is connected to the mounting plate by screws, and the drive motor is connected to the drive cylinder by a coupling.

[0009] Preferably, a material injection door is installed on the other side of the upper surface of the isolation grinding box, and the material injection door is connected to the isolation grinding box by a hinge.

[0010] Preferably, sound insulation pads are installed on the inner sides of the injection door, the isolation grinding box, and the mounting plate, and the sound insulation pads are glued to the injection door, the isolation grinding box, and the mounting plate.

[0011] Preferably, support legs are installed on both sides of the lower end face of the isolation grinding box, and the support legs are welded to the isolation grinding box.

[0012] Preferably, a partition plate is installed on one side of the lower end of the interior of the isolation grinding box, and the partition plate is welded to the isolation grinding box.

[0013] Preferably, the spiral grinding bracket has abrasive balls inside, and a flow guide bracket is installed at one end of the spiral grinding bracket, which is fixedly connected to the spiral grinding bracket.

[0014] Preferably, a control box is installed on the front end face of the isolation grinding box, and the control box is connected to the isolation grinding box by screws.

[0015] Compared with the prior art, the beneficial effects of this utility model are:

[0016] 1. This utility model, by installing a spiral grinding bracket and rotating it in conjunction with a drive cylinder, allows the abrasive balls inside the spiral grinding bracket to collide and rub against each other with the cam plates as the spiral grinding bracket rotates. This causes the abrasive balls to grind the cam plates, improving their quality. When the spiral grinding bracket is grinding the cam plates, the operator can add different batches of cam plates into the spiral grinding bracket multiple times, allowing the device to grind different batches of cam plates. Furthermore, different batches of cam plates will not mix when added into the spiral grinding bracket, improving the grinding efficiency and ensuring that different batches of cam plates have a consistent grinding effect when discharged from the device.

[0017] 2. This utility model can filter impurities by installing an impurity filter screen, allowing the impurities to be discharged from the device, making it convenient for staff to collect and clean the impurities, thus enhancing the practicality of the device. Installing a sound insulation pad can isolate the noise generated by grinding inside the device, preventing a large amount of noise from spreading to the outside, making the device more user-friendly and providing staff with a good working environment. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the internal structure of a cam plate anti-wear cutting structure according to the present invention;

[0019] Figure 2 This is a three-dimensional perspective view of a cam plate anti-wear cutting wire machining structure according to the present invention;

[0020] Figure 3 This is a bottom view of a cam plate anti-wear cutting line machining structure according to the present invention;

[0021] Figure 4 This diagram shows the connection relationship between the drive cylinder and the spiral grinding bracket of this utility model.

[0022] In the diagram: 1. Isolation grinding box; 2. Mounting plate; 3. Sound insulation pad; 4. Injection gate; 5. Drive cylinder; 6. Spiral grinding bracket; 7. Flow guide bracket; 8. Waste discharge trough; 9. Impurity filter screen; 10. Support leg; 11. Discharge trough; 12. Divider plate; 13. Drive motor; 14. Control box. 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 of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0024] Please see Figure 1-4 One embodiment of this utility model is a cam plate anti-wear cutting structure, including an isolation grinding box 1.

[0025] Mounting plates 2 are welded to both sides of the isolation grinding box 1. There are two mounting plates 2, and a drive cylinder 5 is rotatably mounted between the two mounting plates 2 via a bearing. A spiral grinding bracket 6 is fixedly mounted on the outside of the drive cylinder 5. The spiral grinding bracket 6 is installed to cooperate with the drive cylinder 5 to rotate, so that the abrasive balls inside the spiral grinding bracket 6 collide and rub against each other with the cam plate when the spiral grinding bracket 6 rotates, thereby grinding the cam plate and improving the quality of the cam plate. When grinding the cam plate, the operator can add different batches of cam plates into the spiral grinding bracket 6 in multiple batches, so that the device can grind different batches of cam plates. When different batches of cam plates are added into the spiral grinding bracket 6, they will not mix, improving the grinding efficiency of the cam plate and ensuring that the grinding effect of different batches of cam plates is consistent when they are discharged from the device. The spiral grinding bracket 6 is externally set with a mesh structure.

[0026] Waste discharge trough 8 is located at the lower end of the isolation grinding box 1. The waste discharge trough 8 is equipped with an impurity filter screen 9. The impurity filter screen 9 can filter impurities and allow them to be discharged from the device, making it convenient for staff to collect and clean the impurities, thus enhancing the practicality of the device. The impurity filter screen 9 is fixedly connected to the isolation grinding box 1. A discharge trough 11 is provided on one side of the lower end face of the isolation grinding box 1.

[0027] Please see Figure 1 , Figure 2 , Figure 3 and Figure 4 A drive motor 13 is installed on one side of the isolation grinding box 1. The drive motor 13 is connected to the mounting plate 2 by screws, and the drive motor 13 is connected to the drive cylinder 5 by a coupling. A filling door 4 is installed on the other side of the upper surface of the isolation grinding box 1. The filling door 4 is connected to the isolation grinding box 1 by a hinge. Sound insulation pads 3 are installed on the inner sides of the filling door 4, the isolation grinding box 1, and the mounting plate 2. Installing the sound insulation pads 3 can isolate the noise generated during grinding inside the device, preventing a large amount of noise from spreading to the outside, making the device more user-friendly, and providing workers with a good working environment. The sound insulation pads 3 and the filling door 4 are connected to the mounting plate 2 by screws. Material gate 4, isolation grinding box 1 and mounting plate 2 are all glued together. Support legs 10 are installed on both sides of the lower end face of isolation grinding box 1. The support legs 10 are welded to isolation grinding box 1. A partition plate 12 is installed on one side of the lower end inside isolation grinding box 1. The partition plate 12 is welded to isolation grinding box 1. Abrasive balls are set inside the spiral grinding bracket 6. A flow guide bracket 7 is installed at one end of spiral grinding bracket 6. The flow guide bracket 7 is fixedly connected to spiral grinding bracket 6. A control box 14 is installed on the front end face of isolation grinding box 1. The control box 14 is connected to isolation grinding box 1 by screws.

[0028] Working principle: During use, the operator opens the filling gate 4 and places the first batch of cam plates and abrasive balls into the guide bracket 7, allowing the first batch of cam plates to enter the spiral grinding bracket 6. Then, the drive motor 13 drives the drive cylinder 5 and the spiral grinding bracket 6 to rotate 360 ​​degrees. The operator then places the second batch of cam plates and abrasive balls into the guide bracket 7, allowing the second batch of cam plates to enter the spiral grinding bracket 6. The drive motor 13 then drives the drive cylinder 5 and the spiral grinding bracket 6 to rotate 360 ​​degrees, and so on. The device can continuously grind multiple batches of cam plates, achieving streamlined production and improving grinding efficiency. The first batch of cam plates and abrasive balls gradually move inside the spiral grinding bracket 6 to one end near the discharge chute 11. During this movement, the cam plates and abrasive balls rub against each other, causing the abrasive balls to grind the cam plates. As the drive cylinder 5 and the spiral grinding bracket 6 rotate continuously, the first batch of ground cam plates and abrasive balls are discharged from the spiral grinding bracket 6. Then, the cam plates and abrasive balls are discharged from the device through the discharge chute 11. The operator then cleans the abrasive balls... The grinding balls are recycled and added back to the spiral grinding bracket 6 along with the next batch of cam plates for reuse. The device is equipped with the spiral grinding bracket 6 to rotate in conjunction with the drive cylinder 5. This allows the abrasive balls inside the spiral grinding bracket 6 to collide and rub against the cam plates as the spiral grinding bracket 6 rotates, thus grinding the cam plates and improving their quality. During the grinding of the cam plates, operators can add different batches of cam plates to the spiral grinding bracket 6 multiple times, allowing the device to grind different batches of cam plates. The grinding process ensures that different batches of cams do not mix when added to the spiral grinding bracket 6, thus improving grinding efficiency and ensuring consistent grinding results when discharged from the device. The installation of an impurity filter screen 9 filters impurities, allowing them to be discharged and facilitating collection and cleaning by staff, enhancing the device's practicality. The installation of a sound insulation pad 3 isolates noise generated during internal grinding, preventing excessive noise diffusion and making the device more user-friendly, providing staff with a comfortable working environment.

[0029] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A cam piece anti-abrasion line machining structure, comprising an isolated grinding box (1), characterized in that: mounting plates (2) are welded and mounted on both sides of the isolated grinding box (1), two mounting plates (2) are provided, a driving cylinder (5) is rotatably mounted between the two mounting plates (2) through a bearing, a spiral grinding support (6) is fixedly mounted outside the driving cylinder (5), and the spiral grinding support (6) is provided in a mesh structure outside. A waste discharge groove (8) is arranged at the lower end of the isolated grinding box (1), an impurity filter screen (9) is mounted in the waste discharge groove (8), the impurity filter screen (9) is fixedly connected with the isolated grinding box (1), and a discharge groove (11) is arranged on one side of the lower end surface of the isolated grinding box (1). A driving motor (13) is arranged on one side of the isolated grinding box (1), the driving motor (13) is connected with the mounting plate (2) through screws, and the driving motor (13) is connected with the driving cylinder (5) through a shaft coupling.

2. The cam profile wear prevention line processing structure according to claim 1, characterized by: A material injection door (4) is mounted on the other side of the upper end surface of the isolated grinding box (1), and the material injection door (4) is connected with the isolated grinding box (1) through a hinge.

3. The cam profile wear prevention line processing structure according to claim 1, characterized by: Sound insulation pads (3) are mounted on the inner sides of the material injection door (4), the isolated grinding box (1) and the mounting plate (2), and the sound insulation pads (3) are adhesively connected with the material injection door (4), the isolated grinding box (1) and the mounting plate (2).

4. The cam profile wear prevention line processing structure according to claim 3, characterized by: Support legs (10) are mounted on both sides of the lower end surface of the isolated grinding box (1), and the support legs (10) are welded and connected with the isolated grinding box (1).

5. The cam profile wear prevention line processing structure according to claim 1, characterized by: A partition plate (12) is mounted on one side of the lower end inside the isolated grinding box (1), and the partition plate (12) is welded and connected with the isolated grinding box (1).

6. The cam profile wear strip according to claim 1, wherein: Abrasive small balls are arranged in the spiral grinding support (6), a flow guide support (7) is mounted at one end of the spiral grinding support (6), and the flow guide support (7) is fixedly connected with the spiral grinding support (6).

7. The cam profile wear strip according to claim 1, wherein: A control box (14) is mounted on the front end surface of the isolated grinding box (1), and the control box (14) is connected with the isolated grinding box (1) through screws.

8. The cam profile wear strip according to claim 1, wherein: ​