CN108356644B

CN108356644B - Polishing cutter for protecting lens

Info

Publication number: CN108356644B
Application number: CN201810055058.4A
Authority: CN
Inventors: 王伟; 高亮; 陈松; 陈诗绍; 夏军伟
Original assignee: Weidali Technology Co ltd; Vitalink Industry Shenzhen Co ltd
Current assignee: Weidali Technology Co ltd; Vitalink Industry Shenzhen Co ltd
Priority date: 2018-01-19
Filing date: 2018-01-19
Publication date: 2024-06-18
Anticipated expiration: 2038-01-19
Also published as: CN108356644A

Abstract

The invention relates to a polishing cutter for protecting lenses, which comprises a drilling part, a first sand separation section, a finishing surface polishing section, a rough ore surface polishing section and a main driving shaft. The drilling part, the first sand separation section, the finishing surface polishing section, the rough ore surface polishing section and the main driving shaft are sequentially connected and coaxially arranged. The fine finishing surface polishing section and the coarse ore surface polishing section are columnar, and the outer diameter of the fine finishing surface polishing section is smaller than that of the coarse ore surface polishing section. The polishing tool for protecting the lens is characterized in that when the rough ore surface polishing section carries out rough grinding on the inner side wall of the through hole, the finishing surface polishing section is not subjected to larger processing stress, so that the finishing surface polishing section is not broken or deformed, the service life of the polishing tool for protecting the lens can be prolonged, the cost is reduced, the tool changing frequency in the production process can be reduced, the reduction of the product quality caused by tool changing is avoided, and the production efficiency is improved.

Description

Polishing cutter for protecting lens

Technical Field

The present invention relates to polishing tools, and more particularly to a polishing tool for protecting lenses.

Background

The traditional grinding cutter for protecting the lenses comprises a drill bit, a rough ore surface grinding section, a finish surface grinding section and a main shaft, wherein the drill bit, the rough ore surface grinding section and the finish surface grinding section are sequentially connected, and the main shaft is used for being connected to a torque output shaft of a driving motor. The operation steps of processing the through hole on the protective lens are as follows: firstly, a through hole is drilled on a protective lens through a drill, then the inner side wall of the through hole is roughly ground by adopting a rough ore surface grinding section, and then the inner side wall of the through hole is finely ground by adopting a finish surface grinding section, so that the through hole can be manufactured on the protective lens. However, in the course of rough grinding of the inner side wall of the through hole, breakage or deformation easily occurs at the finishing surface grinding section, resulting in a short service life of the grinding tool for protecting the lens.

Disclosure of Invention

Based on this, it is necessary to overcome the defects of the prior art and provide a polishing tool for protecting lenses with a longer service life.

The technical scheme is as follows: a lens-protecting sanding tool comprising: the device comprises a drilling part, a first sand separation section, a finishing surface polishing section, a rough ore surface polishing section and a main driving shaft; the drilling part, the first sand separation section, the finishing surface polishing section, the coarse ore surface polishing section and the main driving shaft are sequentially connected, and the drilling part, the first sand separation section, the finishing surface polishing section, the coarse ore surface polishing section and the main driving shaft are coaxially arranged; the finishing surface polishing section and the coarse ore surface polishing section are columnar, and the outer diameter of the finishing surface polishing section is smaller than that of the coarse ore surface polishing section.

When the polishing cutter for the protective lens polishes the protective lens, the through hole can be drilled on the protective lens by the drilling part, and the through hole can be a decorative hole, a camera hole, a voice hole and the like; the side wall of the rough ore surface polishing section is contacted with the inner side wall of the through hole, and the rough ore surface polishing section carries out rough grinding on the inner side wall of the through hole under the condition that the motor drives the main driving shaft to rotate; and then the side wall of the finishing surface polishing section is contacted with the inner side wall of the through hole, and the finishing surface polishing section carries out fine grinding processing on the inner side wall of the through hole under the condition that the motor drives the main driving shaft to rotate. When rough grinding is carried out on the inner side wall of the through hole in the rough ore surface grinding section, the finishing surface grinding section is not subjected to larger processing stress, so that the finishing surface grinding section is not broken or deformed, the service life of a grinding tool for protecting lenses can be prolonged, the cost is reduced, the tool changing frequency in the production process can be reduced, the reduction of the product quality caused by tool changing is avoided, and the production efficiency is improved.

Further, a first diamond sand layer is arranged on the surface of the drilling part, and the mesh number of the first diamond sand layer is 300-600 meshes; the surface of the finishing surface polishing section is provided with a second diamond sand layer, and the mesh number of the second diamond sand layer is 1000-1400 meshes; the surface of the coarse ore surface polishing section is provided with a third diamond sand layer, and the mesh number of the third diamond sand layer is 300-600 meshes.

Further, the mesh number of the first gold steel sand layer is 400-500 mesh, the mesh number of the second gold steel sand layer is 1200-1300 mesh, and the mesh number of the third gold steel sand layer is 400-500 mesh.

Further, the polishing tool for protecting the lens further comprises a transition section, a coarse-profile polishing section, a second sand separation section and a fine-profile polishing section which are arranged between the coarse-profile polishing section and the main driving shaft, wherein the coarse-profile polishing section, the transition section, the coarse-profile polishing section, the second sand separation section, the fine-profile polishing section and the main driving shaft are sequentially connected and coaxially arranged, the outer diameter of the coarse-profile polishing section is larger than that of the transition section, the outer diameter of the transition section gradually increases from one end, which is close to the coarse-profile polishing section, to one end, which is close to the coarse-profile polishing section, and the coarse-profile polishing section and the fine-profile polishing section are columnar.

Further, a fourth diamond sand layer is arranged on the surface of the coarse-outline polishing section, and the mesh number of the fourth diamond sand layer is 300-600 meshes; the surface of the fine-appearance polishing section is provided with a fifth diamond sand layer, and the mesh number of the fifth diamond sand layer is 1000-1400 meshes.

Further, the mesh number of the fourth gold steel sand layer is 400-500 meshes, and the mesh number of the fifth gold steel sand layer is 1200-1300 meshes.

Further, the polishing tool for protecting the lens further comprises a columnar section arranged between the fine-profile polishing section and the main driving shaft, the fine-profile polishing section, the columnar section and the main driving shaft are sequentially connected and coaxially arranged, the outer diameter of the columnar section is larger than that of the fine-profile polishing section, a fine-grinding cambered surface is arranged on the side wall of the columnar section facing the drilling part, and a coarse-grinding cambered surface is arranged on the side wall of the coarse-profile polishing section facing the drilling part.

Further, the rough grinding cambered surface is provided with a sixth diamond sand layer, and the mesh number of the sixth diamond sand layer is 300-600 meshes; the surface of the fine grinding cambered surface is provided with a seventh diamond sand layer, and the mesh number of the seventh diamond sand layer is 1000-1400 meshes.

Further, the mesh number of the sixth gold steel sand layer is 400-500 mesh, and the mesh number of the seventh gold steel sand layer is 1200-1300 mesh.

Further, the changeover portion includes first cone section, first reserve thick appearance section of polishing, second cone section and second reserve thick appearance section of polishing, first cone section first reserve thick appearance section of polishing second cone section with second reserve thick appearance section of polishing connects gradually and coaxial setting, first reserve thick appearance section of polishing second reserve thick appearance section of polishing all is the column.

Drawings

FIG. 1 is a schematic view of a polishing tool for protecting a lens according to an embodiment of the present invention;

Fig. 2 is a schematic diagram illustrating a state that a polishing tool for protecting a lens drills a hole on the protecting lens according to an embodiment of the present invention;

Fig. 3 is a schematic diagram showing a state that a grinding tool for protecting a lens performs rough ore surface processing on a through hole of the protecting lens according to an embodiment of the present invention;

fig. 4 is a schematic diagram showing a state that a polishing tool for protecting a lens performs finishing processing on a through hole of the protecting lens according to an embodiment of the present invention;

FIG. 5 is a schematic view showing a polishing tool for protecting a lens according to an embodiment of the present invention performing rough-shape processing on an edge of the protective lens;

FIG. 6 is a schematic view showing a polishing tool for protecting a lens according to an embodiment of the present invention performing a fine profile process on an edge of the protective lens;

Fig. 7 is a schematic diagram of a state in which a grinding tool for protecting a lens performs rough grinding on an edge side surface of the protective lens according to an embodiment of the present invention;

fig. 8 is a schematic diagram illustrating a state in which a grinding tool for protecting a lens performs fine grinding of an arc surface on an edge side surface of the protecting lens according to an embodiment of the present invention.

Reference numerals:

10. Drilling part, 20, first sand-separating section, 30, finishing surface polishing section, 40, rough ore surface polishing section, 50, main driving shaft, 60, transition section, 61, first cone section, 62, first standby rough appearance polishing section, 63, second cone section, 64, second standby rough appearance polishing section, 70, rough appearance polishing section, 71, rough grinding cambered surface, 80, second sand-separating section, 90, fine appearance polishing section, 100, columnar section, 110, fine grinding cambered surface, 200, protective lens, 210 and through hole.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the invention, whereby the invention is not limited to the specific embodiments disclosed below.

In the description of the present invention, it should be understood that the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the description of the present invention, it will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly connected" to another element, there are no intervening elements present.

In one embodiment, as shown in fig. 1, a lens-protecting sanding tool includes a drilling section 10, a first sand screen section20, a finishing face sanding section 30, a rough mining face sanding section 40, and a main drive shaft 50. The drilling part 10, the first sand separation section20, the finishing surface polishing section 30, the coarse ore surface polishing section 40 and the main driving shaft 50 are sequentially connected, and the drilling part 10, the first sand separation section20, the finishing surface polishing section 30, the coarse ore surface polishing section 40 and the main driving shaft 50 are coaxially arranged. The finishing surface polishing section 30 and the rough ore surface polishing section 40 are columnar, and the outer diameter of the finishing surface polishing section 30 is smaller than the outer diameter of the rough ore surface polishing section 40.

In the polishing tool for protecting a lens, referring to fig. 2 to 4, when polishing the protecting lens 200, a through hole 210 may be drilled on the protecting lens 200 by the drilling portion 10, and the through hole 210 may be a decorative hole, a camera hole, a voice hole, etc.; the side wall of the rough ore face grinding section 40 is contacted with the side wall of the through hole 210, and the rough ore face grinding section 40 carries out rough grinding on the side wall of the through hole 210 under the condition that the motor drives the main driving shaft 50 to rotate; the sidewall of the finishing surface grinding segment 30 is then brought into contact with the inner sidewall of the through-hole 210, and the finishing surface grinding segment 30 performs finish grinding on the inner sidewall of the through-hole 210 while the motor drives the main driving shaft 50 to rotate. When rough grinding is carried out on the inner side wall of the through hole 210 by the rough ore surface grinding section 40, the finishing surface grinding section 30 cannot receive larger processing stress, so that the finishing surface grinding section 30 cannot break or deform, the service life of a grinding tool for protecting lenses can be prolonged, the cost is reduced, the tool changing frequency in the production process can be reduced, the reduction of the product quality caused by tool changing is avoided, and the production efficiency is improved.

Further, the surface of the drilling portion 10 is provided with a first diamond sand layer having a mesh number of 300 mesh to 600 mesh. The surface of the finishing surface polishing section 30 is provided with a second diamond sand layer, and the mesh number of the second diamond sand layer is 1000-1400 meshes. The surface of the coarse ore surface polishing section 40 is provided with a third diamond sand layer, and the mesh number of the third diamond sand layer is 300-600 meshes. Thus, the polishing tool for protecting the lens has higher processing precision and higher processing efficiency on the through hole 210 on the protecting lens 200. Specifically, the mesh number of the first gold steel sand layer is 400-500 mesh, the mesh number of the second gold steel sand layer is 1200-1300 mesh, and the mesh number of the third gold steel sand layer is 400-500 mesh.

Further, referring to fig. 5 and 6 together, the lens-protecting polishing tool further comprises a transition section 60, a rough profile polishing section 70, a second sand separation section 80 and a fine profile polishing section 90 disposed between the rough mining face polishing section 40 and the main driving shaft 50. The rough ore surface polishing section 40, the transition section 60, the rough profile polishing section 70, the second sand separation section 80, the fine profile polishing section 90, and the main drive shaft 50 are sequentially connected and coaxially arranged. The outer diameter of the rough grinding section 70 is larger than the outer diameter of the transition section 60, and the outer diameter of the transition section 60 gradually increases from one end close to the rough grinding section 40 to one end close to the rough grinding section 70. The coarse profile grinding section 70 and the fine profile grinding section 90 are both cylindrical. In this way, the rough grinding section 70 may be first contacted with the edge of the protective lens 200, and the rough grinding process is performed on the edge of the protective lens 200 by the rough grinding section 40 under the rotation of the motor-driven main driving shaft 50; then, the fine profile grinding section 90 is brought into contact with the edge of the protective lens 200, and the fine profile grinding section 90 performs fine grinding of the edge of the protective lens 200 under rotation of the motor-driven main driving shaft 50, so that the grinding accuracy of the edge of the protective lens 200 can be ensured.

Further, a fourth diamond sand layer is arranged on the surface of the rough-shape polishing section 70, and the mesh number of the fourth diamond sand layer is 300-600 meshes. The surface of the fine-profile polishing section 90 is provided with a fifth diamond sand layer, and the mesh number of the fifth diamond sand layer is 1000-1400 meshes. Thus, the polishing cutter for protecting the lens has higher polishing precision and higher processing efficiency on the edge surface on the protecting lens 200. Specifically, the mesh number of the fourth gold steel sand layer is 400-500 meshes, and the mesh number of the fifth gold steel sand layer is 1200-1300 meshes.

Further, referring to fig. 7 and 8 together, the lens-protecting sanding tool further includes a cylindrical section 100 disposed between the fine profile sanding section 90 and the main drive shaft 50. The fine profile grinding section 90, the cylindrical section 100 are connected in sequence and coaxially disposed with the main drive shaft 50. The outer diameter of the columnar section 100 is larger than that of the fine-profile polishing section 90, a fine-grinding cambered surface 110 is arranged on the side wall of the columnar section 100 facing the drilling part 10, and a coarse-grinding cambered surface 71 is arranged on the side wall of the coarse-profile polishing section 70 facing the drilling part 10. In this way, the rough grinding cambered surface 71 can be contacted with the edge side surface of the protective lens 200, and the rough grinding process is performed on the edge side surface of the protective lens 200 by the rough grinding section 40 under the rotation of the motor-driven main driving shaft 50; then, the fine profile grinding section 90 is brought into contact with the edge side surface of the protective lens 200, and the fine profile grinding section 90 performs fine grinding processing on the edge side surface of the protective lens 200 under rotation of the motor-driven main drive shaft 50, so that an arc surface with high accuracy can be formed on the edge side surface of the protective lens 200.

Further, the rough grinding cambered surface 71 is provided with a sixth diamond sand layer, and the mesh number of the sixth diamond sand layer is 300 meshes to 600 meshes. The surface of the fine grinding cambered surface 110 is provided with a seventh diamond sand layer, and the mesh number of the seventh diamond sand layer is 1000-1400 meshes. Thus, the polishing cutter for protecting the lens has higher polishing precision and higher processing efficiency on the edge side surface on the protecting lens 200. Specifically, the mesh number of the sixth gold steel sand layer is 400-500 mesh, and the mesh number of the seventh gold steel sand layer is 1200-1300 mesh.

In one embodiment, referring to fig. 1 again, the transition section 60 includes a first cone section 61, a first spare rough-profile grinding section 7062, a second cone section 63, and a second spare rough-profile grinding section 7064, where the first cone section 61, the first spare rough-profile grinding section 7062, the second cone section 63, and the second spare rough-profile grinding section 7064 are sequentially connected and coaxially disposed, and the first spare rough-profile grinding section 7062 and the second spare rough-profile grinding section 7064 are all columnar. In this manner, when the fourth diamond grit layer on the surface of the rough grinding stage 70 is worn away and loses the grinding effect, the edge of the protective lens 200 can be rough-contoured with either the first backup rough grinding stage 7062 or the second backup rough outer grinding stage. Specifically, the surfaces of the first standby coarse grinding section 7062 and the second standby coarse grinding section 7064 are also provided with diamond sand layers, and the mesh number of the diamond sand layers is the same as that of the diamond sand layers on the surface of the coarse grinding section 70.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims

1. A lens-protecting sanding tool, comprising: the device comprises a drilling part, a first sand separation section, a finishing surface polishing section, a coarse ore surface polishing section, a transition section, a coarse appearance polishing section, a second sand separation section, a finishing appearance polishing section and a main driving shaft; the drilling part, the first sand separation section, the finishing surface polishing section, the coarse ore surface polishing section, the transition section, the coarse appearance polishing section, the second sand separation section, the fine appearance polishing section and the main driving shaft are sequentially connected, and the drilling part, the first sand separation section, the finishing surface polishing section, the coarse ore surface polishing section, the transition section, the coarse appearance polishing section, the second sand separation section, the fine appearance polishing section and the main driving shaft are coaxially arranged; the finishing surface polishing section, the coarse ore surface polishing section, the coarse appearance polishing section and the fine appearance polishing section are all columnar, the outer diameter of the finishing surface polishing section is smaller than that of the coarse ore surface polishing section, and the outer diameter of the coarse appearance polishing section is larger than that of the transition section;

The surface of the drilling part is provided with a first diamond sand layer, and the mesh number of the first diamond sand layer is 300-600 meshes; the surface of the finishing surface polishing section is provided with a second diamond sand layer, and the mesh number of the second diamond sand layer is 1000-1400 meshes; a third diamond sand layer is arranged on the surface of the coarse ore surface polishing section, and the mesh number of the third diamond sand layer is 300-600 meshes;

The transition section comprises a first cone section, a first standby rough-appearance polishing section, a second cone section and a second standby rough-appearance polishing section, wherein the first cone section, the first standby rough-appearance polishing section, the second cone section and the second standby rough-appearance polishing section are sequentially connected and coaxially arranged, and the first standby rough-appearance polishing section and the second standby rough-appearance polishing section are columnar; the first cone section is connected with the coarse ore surface polishing section, and the second standby coarse outline polishing section is connected with the coarse outline polishing section; the outer diameters of the first cone section, the first standby coarse appearance polishing section, the second cone section and the second standby coarse appearance polishing section are sequentially increased.

2. The lens-protecting sanding tool of claim 1, wherein the first layer of gold steel sand has a mesh size of 400 mesh to 500 mesh, the second layer of gold steel sand has a mesh size of 1200 mesh to 1300 mesh, and the third layer of gold steel sand has a mesh size of 400 mesh to 500 mesh.

3. The lens-protecting polishing tool according to claim 1, wherein a fourth diamond sand layer is arranged on the surface of the rough-profile polishing section, and the mesh number of the fourth diamond sand layer is 300-600 mesh; the surface of the fine-appearance polishing section is provided with a fifth diamond sand layer, and the mesh number of the fifth diamond sand layer is 1000-1400 meshes.

4. A lens-protecting sanding tool according to claim 3, wherein the fourth layer of gold steel sand has a mesh size of 400 mesh to 500 mesh and the fifth layer of gold steel sand has a mesh size of 1200 mesh to 1300 mesh.

5. The lens-protecting grinding tool according to claim 1, further comprising a columnar section disposed between the fine-profile grinding section and the main drive shaft, the fine-profile grinding section, the columnar section and the main drive shaft being sequentially connected and coaxially disposed, an outer diameter of the columnar section being larger than an outer diameter of the fine-profile grinding section, a fine grinding cambered surface being provided on a side wall of the columnar section facing the drilling portion, and a coarse grinding cambered surface being provided on a side wall of the coarse-profile grinding section facing the drilling portion.

6. The lens-protecting grinding tool according to claim 5, wherein the rough grinding cambered surface is provided with a sixth diamond sand layer, and the mesh number of the sixth diamond sand layer is 300-600 mesh; the surface of the fine grinding cambered surface is provided with a seventh diamond sand layer, and the mesh number of the seventh diamond sand layer is 1000-1400 meshes.

7. The lens-protecting sanding tool of claim 6, wherein the sixth layer of gold steel sand has a mesh size of 400 mesh to 500 mesh and the seventh layer of gold steel sand has a mesh size of 1200 mesh to 1300 mesh.