A drilling machine platform for non-ferrous alloy machining

Abstract

The utility model discloses a drilling machine platform for non -ferrous metal alloy processing, including the casing, set up in the processing subassembly and moving platform of casing, be equipped with the extension frame through the opening on the casing, the opening is with the extension frame in together through drive motor and is equipped with the in -out screw rod, the moving platform is through the moving mechanism and is connected with the in -out screw rod, be equipped with four rotating grooves and a transmission chamber on the moving platform. In the utility model, the moving platform can be moved from the outside to the inside of the casing and processed, and then moved to the initial position after processing. This avoids the influence of the processing assembly on the operator when taking and placing materials. And in the process of moving the moving platform into the casing, the positioning disc can be automatically driven to move close, achieving the alignment and clamping of the circular non-ferrous metal alloy. After processing, the positioning disc can also automatically separate and release clamping, improving the processing efficiency and automation degree.

Description

Technical Field

[0001] This utility model relates to the field of machining technology, and in particular to a drilling platform for machining non-ferrous metal alloys. Background Technology

[0002] In the field of machining, drilling machines are commonly used equipment for machining holes in materials such as non-ferrous metal alloys. However, the existing platform design of drilling machines has significant defects, which have an adverse impact on operator safety and machining efficiency.

[0003] Traditional drilling machine platforms have their worktables fixed below the machining components. This layout presents operators with significant safety risks during material handling. Specifically, when operators come into contact with the machining area, the sharp tips of the exposed drill bit can cause deep cuts, accompanied by bleeding, pain, and even impaired hand function. The high temperatures generated during machining in the cutting area can also cause burns to the operator's hands, resulting in redness, swelling, blisters, and in severe cases, infection. These safety risks not only directly threaten the operator's health and may lead to production interruptions and reduced processing efficiency due to injuries, but also cause problems such as employee compensation and production disruptions, negatively impacting the company's economic benefits and social reputation. Therefore, there is an urgent need for a drilling machine platform specifically designed for non-ferrous metal alloy machining to address these issues. Utility Model Content

[0004] The purpose of this utility model is to provide a drilling platform for processing non-ferrous metal alloys, so as to solve the problem mentioned in the background art that the worktable of the traditional drilling platform is fixedly set below the processing components, which leads to a high safety risk for operators when picking up and placing materials in actual operation.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a drilling platform for processing non-ferrous metal alloys, comprising a housing, a processing assembly and a moving stage disposed within the housing, an extension frame provided on the housing through an opening, and an infeed screw provided within the opening and the extension frame via a drive motor, the moving stage being connected to the infeed screw via a moving mechanism, the moving stage being provided with four rotating slots and a transmission chamber, each of the four rotating slots having an adjusting screw extending into the transmission chamber, the transmission chamber having a vertical shaft rotatably disposed therein, the adjusting screw being connected to the vertical shaft via the transmission mechanism, a rack being provided on the inner wall of the opening, one end of the adjusting screw extending to the outside of the moving stage and connected to the rack via the rotating mechanism, a positioning plate being provided on the upper surface of the moving stage, the positioning plate being connected to the adjusting screw via an adjusting mechanism.

[0006] Preferably, the moving mechanism includes a moving plate installed at the bottom of the moving platform, and the moving plate is threadedly mounted on the inlet and outlet screw.

[0007] Preferably, the transmission mechanism includes a horizontal gear mounted on a vertical shaft, and the adjusting screw is provided with a vertical gear that meshes with the horizontal gear.

[0008] Preferably, the rotating mechanism includes an external gear mounted on one of the adjusting screws, the external gear meshing with a rack.

[0009] Preferably, the adjustment mechanism includes an adjustment plate installed at the bottom of the positioning plate, and the adjustment plate is threadedly fitted onto the adjustment screw.

[0010] Preferably, the horizontal gear and the vertical gear are both bevel gears and mesh perpendicularly with each other, and the external gear is a spherical gear.

[0011] The beneficial effects of this utility model are:

[0012] 1. The mobile stage can be moved from the outside of the housing to the inside for processing, and then moved back to its initial position after processing is completed. This avoids the operator being affected by the processing components when picking up and placing materials, reduces the risk of injury from contact with the processing components, and greatly improves operational safety.

[0013] 2. During the process of the moving stage entering the housing, the meshing of the external gear and rack, gear transmission, and the rotation of the adjusting screw automatically drive the positioning plate to move closer, realizing the alignment and clamping of the round non-ferrous metal alloy. After processing is completed, the positioning plate can automatically separate and release the clamp, improving processing efficiency and automation.

[0014] 3. The design of vertical meshing of bevel gears (horizontal and vertical gears) and spherical gears (external gears) saves space and makes the structure of the drilling platform more compact.

[0015] 4. The circular non-ferrous metal alloy is aligned and clamped by the positioning plate, and the upper end is limited by the downward pressure of the limiting plate, which ensures the stability of the material during the processing and helps to improve the processing accuracy. Attached Figure Description

[0016] Figure 1 This is a three-dimensional structural schematic diagram of a drilling platform used for machining non-ferrous metal alloys.

[0017] Figure 2 This is a schematic diagram of the vertical section of a drilling platform used for processing non-ferrous metal alloys.

[0018] Figure 3 for Figure 2 Enlarged schematic diagram of the structure at point A;

[0019] Figure 4 for Figure 2Enlarged schematic diagram of the structure at point B.

[0020] In the diagram: 1. Housing; 2. Opening; 3. Extension frame; 4. Moving stage; 5. Infeed / outfeed screw; 6. Positioning plate; 7. Limiting plate; 8. Transmission chamber; 9. Vertical shaft; 10. Rotating groove; 11. Adjusting screw; 12. Horizontal gear; 13. Vertical gear; 14. Moving plate; 15. Hidden groove; 16. External gear; 17. Rack; 18. Adjusting plate. Detailed Implementation

[0021] 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.

[0022] Reference Figure 1-4 A drilling platform for processing non-ferrous metal alloys includes a housing 1, a processing assembly (which mainly includes a lifting assembly and a drilling assembly, etc., as detailed in existing technology, which is not improved in this solution and will not be described in detail here) and a moving stage 4. An extension frame 3 is provided on the housing 1 through an opening 2. An inlet / outlet screw 5 is provided in the opening 2 and the extension frame 3 through a drive motor. The moving stage 4 is connected to the inlet / outlet screw 5 through a moving mechanism. The moving stage 4 is provided with four rotating slots 10 and a transmission chamber 8. An adjusting screw 11 extending into the transmission chamber 8 is rotatably provided in each of the four rotating slots 10. A vertical shaft 9 is rotatably provided in the transmission chamber 8. The adjusting screw 11 is connected to the vertical shaft 9 through the transmission mechanism. A rack 17 is provided on the inner wall of the opening 2. One end of the adjusting screw 11 extends to the outside of the moving stage 4 and is connected to the rack 17 through the rotating mechanism. A positioning plate 6 is provided on the upper surface of the moving stage 4 (the above four positioning plates 6 are circumferentially evenly distributed). The positioning plate 6 is connected to the adjusting screw 11 through the adjusting mechanism.

[0023] The moving mechanism includes a moving plate 14 installed at the bottom of the moving platform 4, which is threaded onto the inlet / outlet screw 5. As shown in the figure, a lower crossbar is also provided on the inner wall of the extension frame 3. This lower crossbar is parallel to the inlet / outlet screw 5 and slides through the moving plate 14, thereby limiting the movement of the moving plate 14.

[0024] The transmission mechanism includes a horizontal gear 12 mounted on a vertical shaft 9, and a vertical gear 13 on an adjusting screw 11 that meshes with the horizontal gear 12. When the horizontal gear 12 rotates, it can drive the adjusting screw 11 to rotate in conjunction with the vertical gear 13.

[0025] The rotating mechanism includes an external gear 16 mounted on one of the adjusting screws 11, which meshes with a rack 17. As the moving platform 4 moves, the adjusting screw 11 can rotate under the action of the external gear 16 and the rack 17, thereby driving the horizontal gear 12 to rotate, which in turn, in conjunction with the vertical gear 13, enables the rotation of the other three adjusting screws 11.

[0026] As shown in the figure, the outer wall of the moving platform 4 is provided with a hidden groove 15, the external gear 16 is located in the hidden groove 15, and the vertical outer walls on both sides of the moving platform 4 are in sliding contact with the vertical inner wall of the extension frame 3.

[0027] The adjustment mechanism includes an adjustment plate 18 installed at the bottom of the positioning plate 6, which is threaded onto the adjustment screw 11. As shown in the figure, an upper crossbar is also provided in the rotating groove 10. This upper crossbar is parallel to the adjustment screw 11 and slides through the adjustment plate 18, thereby limiting the position of the adjustment plate 18.

[0028] Both the horizontal gear 12 and the vertical gear 13 are bevel gears and mesh perpendicularly with each other, while the external gear 16 is a spherical gear. See the attached diagram for details; these types of gears were chosen primarily to save space.

[0029] Components not specifically described in this utility model are all standard parts and can be purchased from the market. The specific connection methods for each component all employ mature methods from the prior art, and will not be detailed here. Content not described in detail in this specification belongs to prior art known to those skilled in the art.

[0030] In the initial state of use, the moving platform 4 is located outside the housing 1, with the four positioning disks 6 spaced apart. A circular non-ferrous metal alloy is placed on the moving platform 4 between the four positioning disks 6. The drive motor is then started, causing the feed screw 5 to rotate. As the feed screw 5 rotates, the moving platform 4 carries the material through the opening 2 into the housing 1. During this process, the external gear 16 meshes with the rack 17, and in the subsequent movement of the moving platform 4, it drives one of the adjusting screws 11 to rotate. The vertical gear 13 on this adjusting screw 11 drives the horizontal gear 12 to rotate. This horizontal gear 12, with the help of the other vertical gears 13, drives the other adjusting screws 11 to rotate. When all four adjusting screws 11 rotate, the adjusting plate 18 moves the positioning disks 6 closer together, ultimately achieving the alignment and clamping of the circular non-ferrous metal alloy. The upper surface of the circular non-ferrous metal alloy is pressed down by the limiting disk 7 to ensure stability.

[0031] After processing is completed, the moving table 4 and other components move in the opposite direction and move out of the opening 2 to the initial position. The four positioning disks 6 can automatically separate and release the clamping and fixing of the circular non-ferrous metal alloy, making it convenient to take it out.

[0032] 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 drilling platform for machining non-ferrous metal alloys, comprising a housing (1), machining components and a moving stage (4) disposed within the housing (1), characterized in that, The housing (1) is provided with an extension frame (3) through an opening (2). The opening (2) and the extension frame (3) are provided with an inlet / outlet screw (5) through a drive motor. The moving platform (4) is connected to the inlet / outlet screw (5) through a moving mechanism. The moving platform (4) is provided with four rotating slots (10) and a transmission chamber (8). Each of the four rotating slots (10) is provided with an adjusting screw (11) extending into the transmission chamber (8). The transmission chamber (8) is provided with a vertical shaft (9). The adjusting screw (11) is connected to the vertical shaft (9) through a transmission mechanism. The inner wall of the opening (2) is provided with a rack (17). The end of one of the adjusting screws (11) extends to the outside of the moving platform (4) and is connected to the rack (17) through a rotating mechanism. The upper surface of the moving platform (4) is provided with a positioning plate (6). The positioning plate (6) is connected to the adjusting screw (11) through an adjusting mechanism.

2. A drilling platform for processing non-ferrous metal alloys according to claim 1, characterized in that, The moving mechanism includes a moving plate (14) installed at the bottom of the moving platform (4), and the moving plate (14) is threadedly installed on the inlet and outlet screw (5).

3. A drilling platform for processing non-ferrous metal alloys according to claim 2, characterized in that, The transmission mechanism includes a horizontal gear (12) mounted on a vertical shaft (9), and a vertical gear (13) meshing with the horizontal gear (12) is provided on the adjusting screw (11).

4. A drilling platform for processing non-ferrous metal alloys according to claim 3, characterized in that, The rotating mechanism includes an external gear (16) mounted on one of the adjusting screws (11), which meshes with a rack (17).

5. A drilling platform for processing non-ferrous metal alloys according to claim 4, characterized in that, The adjustment mechanism includes an adjustment plate (18) installed at the bottom of the positioning plate (6), and the adjustment plate (18) is threadedly installed on the adjustment screw (11).

6. A drilling platform for processing non-ferrous metal alloys according to claim 5, characterized in that, The horizontal gear (12) and the vertical gear (13) are both bevel gears and mesh perpendicularly with each other, while the external gear (16) is a spherical gear.

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