A machining device for titanium alloy parts

By designing an automated clamping, flipping, and recycling mechanism for titanium alloy parts processing, the problem of excess paint recycling was solved, achieving effective resource utilization and cost reduction, while also extending the service life of the device.

CN224405486UActive Publication Date: 2026-06-26GUIYANG HUAFENG AVIATION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUIYANG HUAFENG AVIATION TECH CO LTD
Filing Date
2025-07-21
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing titanium alloy parts processing equipment cannot effectively recover excess paint, resulting in resource waste and increased processing costs.

Method used

A titanium alloy parts processing device was designed, which includes an outer casing, a clamping mechanism, and a circulation mechanism. The clamping mechanism automatically clamps and flips the parts, and the circulation mechanism enables all-round painting. Excess paint is recovered by the conveying component, filtered by the sieve plate, and then pumped out again.

Benefits of technology

It enables the recycling of paint resources, reduces processing costs, and its detachable design facilitates regular maintenance, extending the service life of the equipment.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224405486U_ABST
    Figure CN224405486U_ABST
Patent Text Reader

Abstract

The utility model discloses a kind of processing devices of titanium alloy parts, is related to titanium alloy parts technical field.The processing device of titanium alloy parts, including outer box, clamping mechanism and circulating mechanism, the top of outer box is fixedly connected with shroud, outer box is lap jointed with leakage plate, clamping mechanism includes the hydraulic rod and the interface plate of setting on leakage plate, the free end of hydraulic rod is fixedly connected with interface plate, circulating mechanism includes the paint spraying assembly of setting on outer box and the conveying assembly of setting on paint spraying assembly, paint spraying assembly can move left and right relative to outer box.The design of the component can recycle excess paint, then pump out again after simple sieving, this design can effectively reduce the consumption of paint resources, reduce processing cost, while detachable design is convenient for staff to regularly maintain component, thereby prolong the service life of device, in addition, paint spraying assembly can be driven left and right, can be painted according to the length of part.
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Description

Technical Field

[0001] This utility model relates to the field of titanium alloy parts technology, and in particular to a processing device for titanium alloy parts. Background Technology

[0002] Chinese patent document CN207756319U discloses a novel automated spraying production line. The structure includes a drive box, a mechanical rotator, a power arm, a first connecting arm, a connector, a voltage booster, a gasket, a second connecting arm, a robot rotating head, a spray gun device, and heat dissipation holes. This novel automated spraying production line features a spray gun device, with the lower surface of the gasket connected to the spray gun device. When the automated spraying production line starts working, the spray gun device sprays paint onto the product. The paint material is delivered to the nozzle through the spray gun cavity. The nozzle is energized by the anode, causing the inner wall of the nozzle to receive a large amount of heat. The spray gun cavity is then energized through the cathode rod and cathode plate, filling the spray gun device with plasma. The paint material delivered in the spray gun cavity is heated to a molten state in the plasma flame and sprayed at high speed onto the surface of the part, resulting in high-speed spraying and excellent spraying effect.

[0003] The aforementioned device cannot recycle excess paint, which easily leads to resource waste. In order to address the above problems, improvements have been made to the existing device. Utility Model Content

[0004] The purpose of this invention is to provide a processing device for titanium alloy parts, which can solve the problem that the above-mentioned devices cannot recycle excess paint, which easily leads to resource waste.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a processing device for titanium alloy parts, comprising an outer casing, a clamping mechanism, and a circulation mechanism. A partition is fixedly connected to the top of the outer casing, and a stencil is overlapped and connected to the outer casing. The clamping mechanism includes a hydraulic rod and a connecting plate disposed on the stencil, with the free end of the hydraulic rod fixedly connected to the connecting plate. The circulation mechanism includes a painting assembly disposed on the outer casing and a conveying assembly disposed on the painting assembly. The painting assembly can move left and right relative to the outer casing, and both the painting assembly and the conveying assembly are detachable.

[0006] Preferably, the clamping mechanism further includes an automatic clamping clamp. The connecting plate has a hole, and the automatic clamping clamp is threaded into the hole. This mechanism can automatically flip the parts, thereby cooperating with the circulation mechanism to achieve all-round painting processing.

[0007] Preferably, the painting assembly includes an electric sliding assembly, a connecting frame, a vertical frame, a mechanical spray head, and a conveying pipe. The electric sliding assembly is fixedly connected to the top of the outer casing, and the connecting frame is slidably connected to the electric sliding assembly. The vertical frame is snapped into the connecting frame, and the mechanical spray head is snapped into the vertical frame. The input end of the mechanical spray head is snapped into the conveying pipe. The conveying assembly includes a drawer box, a bracket, a sieve plate, a bend, and a pump. The drawer box is slidably connected to the outer casing, and the bracket is fixedly connected to the inner wall of the drawer box. The sieve plate is laid on the inner side of the bracket, and the output end of the drawer box is snapped into the bend. The pump is fixedly connected to the rear side of the outer casing. This mechanism can recover excess paint through the design of the conveying assembly, and then pump it out again after simple sieving. This design can effectively reduce the consumption of paint resources and reduce processing costs. At the same time, the detachable design makes it convenient for workers to maintain the components regularly, thereby extending the service life of the device. In addition, the painting assembly can be driven left and right, and can be painted according to the length of the parts.

[0008] Preferably, the other end of the bend is snapped into the input end of the pump, and the other end of the delivery pipe is snapped into the input end of the pump.

[0009] Preferably, the internal parts of the drawer, the bend, the pump, the conveying pipe, and the mechanical nozzle are interconnected, and the sieve is made of breathable mesh.

[0010] Preferably, the clamping mechanism is located on the front side of the mechanical nozzle, and the two do not contact each other.

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

[0012] (1) The processing device for the titanium alloy parts, through the combined use of the outer box, partition, sluice plate, clamping mechanism, circulation mechanism, painting component, electric sliding group, connecting frame, upright frame, mechanical spray head, conveying pipe, conveying component, drawer box, bracket, sieve plate, bend pipe and pump, addresses the shortcomings of the above devices in that they cannot recycle excess paint and easily cause resource waste. This mechanism can recycle excess paint through the design of the conveying component, and then pump it out again after simple sieving. This design can effectively reduce the consumption of paint resources and reduce processing costs. At the same time, the disassembly design makes it convenient for staff to maintain the components regularly, thereby extending the service life of the device. In addition, the painting component can be driven left and right, and can be painted according to the length of the part.

[0013] (2) The processing device for the titanium alloy parts, through the combined use of the outer box, partition, sprue, clamping mechanism, hydraulic rod, connecting plate, automatic clamping clamp and circulation mechanism, can automatically flip the parts, thereby cooperating with the circulation mechanism to achieve all-round painting processing. Attached Figure Description

[0014] The present invention will be further described below with reference to the accompanying drawings and embodiments:

[0015] Figure 1 This is an internal view of the present invention;

[0016] Figure 2 This is a perspective view of the present utility model;

[0017] Figure 3 This is a perspective view of the circulation mechanism of this utility model;

[0018] Figure 4 This is an enlarged view of part A of this utility model.

[0019] Reference numerals: 1. Outer casing; 2. Cover; 3. Spray plate; 4. Clamping mechanism; 401. Hydraulic rod; 402. Connecting plate; 403. Automatic clamping clamp; 5. Circulation mechanism; 51. Spray painting assembly; 511. Electric sliding assembly; 512. Connecting frame; 513. Stand; 514. Mechanical spray head; 515. Conveying pipe; 52. Conveying assembly; 521. Drawer box; 522. Bracket; 523. Screen plate; 524. Bend; 525. Pump. Detailed Implementation

[0020] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0021] Please see Figure 1-4 This utility model provides a technical solution: a processing device for titanium alloy parts, including an outer box 1, a clamping mechanism 4 and a circulation mechanism 5. A cover 2 is fixedly connected to the top of the outer box 1, and a stencil 3 is overlapped and connected to the outer box 1. The clamping mechanism 4 includes a hydraulic rod 401 and a connecting plate 402 disposed on the stencil 3. The free end of the hydraulic rod 401 is fixedly connected to the connecting plate 402. The circulation mechanism 5 includes a painting assembly 51 disposed on the outer box 1 and a conveying assembly 52 disposed on the painting assembly 51. The painting assembly 51 can move left and right relative to the outer box 1. Both the painting assembly 51 and the conveying assembly 52 are detachable.

[0022] Furthermore, the clamping mechanism 4 also includes an automatic clamping clamp 403. The connecting plate 402 has a hole, and the automatic clamping clamp 403 is threaded into the hole. In use, the hydraulic rod 401 is started according to the width of the part. The free end of the hydraulic rod 401 drives the connecting plate 402 to rise, and the connecting plate 402 drives the automatic clamping clamp 403 to rise. Then, the part is automatically clamped by the automatic clamping clamp 403. This mechanism can automatically flip the part, thereby cooperating with the circulation mechanism 5 to achieve all-round painting processing.

[0023] Furthermore, the painting assembly 51 includes an electric sliding assembly 511, a connecting frame 512, a stand 513, a mechanical spray head 514, and a conveying pipe 515. The electric sliding assembly 511 is fixedly connected to the top of the outer casing 1. The connecting frame 512 is slidably connected to the electric sliding assembly 511. The stand 513 is snapped into the connecting frame 512. The mechanical spray head 514 is snapped into the stand 513. The input end of the mechanical spray head 514 is snapped into the conveying pipe 515. The conveying assembly 52 includes a drawer 521, a bracket 522, a sieve plate 523, a bend 524, and a pump 525. The drawer 521 is slidably connected inside the outer casing 1. The bracket 522 is fixedly connected to the inner wall of the drawer 521. The sieve plate 523 is laid on the inner side of the bracket 522. The output end of the drawer 521 is snapped into the bend 524. The rear side of the outer casing 1 is fixedly connected to the pump 525. A pump 525 is connected to the fixed connection. The pump 525 is started and pumped through the bend 524 into the conveying pipe 515 to pump the insulating paint in the drawer 521. Then, it is sprayed out from the mechanical nozzle 514 onto the surface of the part. Since the automatic clamp 403 is fully automated, when the part needs to be flipped, the automatic clamp 403 can be driven directly. Excess insulating paint flows through the sieve plate 3 to the filter plate 523 and flows back into the drawer 521. The mechanism can recover excess paint through the design of the conveying component 52. After simple sieving, it can be pumped out again. This design can effectively reduce the consumption of paint resources and reduce processing costs. At the same time, the detachable design makes it easy for the staff to maintain the components regularly, thereby extending the service life of the device. In addition, the painting component 51 can be driven left and right, and can be painted according to the length of the part.

[0024] Secondly, the other end of the bend 524 is snapped into the input end of the pump 525, and the other end of the conveying pipe 515 is snapped into the input end of the pump 525. The internal parts of the drawer 521, bend 524, pump 525, conveying pipe 515 and mechanical nozzle 514 are connected. The sieve plate 523 is made of breathable mesh. The clamping mechanism 4 is located in front of the mechanical nozzle 514, and the two do not contact each other.

[0025] Working principle: In use, the hydraulic rod 401 is started according to the width of the part. The free end of the hydraulic rod 401 drives the connecting plate 402 to rise. The connecting plate 402 drives the automatic clamping clamp 403 to rise. Then, the part is automatically clamped by the automatic clamping clamp 403. The pump 525 is started and the insulating paint in the drawer 521 is pumped into the delivery pipe 515 through the bent pipe 524. Then, it is sprayed out from the mechanical nozzle 514 onto the surface of the part. Since the automatic clamping clamp 403 is fully automated, when the part needs to be flipped, the automatic clamping clamp 403 can be driven directly. Excess insulating paint flows through the sieve plate 3 to the filter plate 523 and flows back into the drawer 521.

[0026] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. An apparatus for machining a titanium alloy part, characterized in that, include: The outer box (1) has a cover (2) fixedly connected to the top, and a slatted plate (3) is connected to the outer box (1). The clamping mechanism (4) includes a hydraulic rod (401) and a connecting plate (402) disposed on the sprue plate (3), and the free end of the hydraulic rod (401) is fixedly connected to the connecting plate (402). The circulation mechanism (5) includes a paint spraying assembly (51) disposed on the outer casing (1) and a conveying assembly (52) disposed on the paint spraying assembly (51). The paint spraying assembly (51) can move left and right relative to the outer casing (1). Both the paint spraying assembly (51) and the conveying assembly (52) are detachable.

2. The apparatus of claim 1, wherein: The clamping mechanism (4) also includes an automatic clamp (403), and the connecting plate (402) has a hole, and the automatic clamp (403) is threadedly connected inside the hole.

3. The processing apparatus for titanium alloy parts according to claim 2, characterized in that: The painting assembly (51) includes an electric sliding assembly (511), a connecting frame (512), a stand (513), a mechanical nozzle (514), and a delivery pipe (515). The electric sliding assembly (511) is fixedly connected to the top of the outer casing (1). The connecting frame (512) is slidably connected to the electric sliding assembly (511). The stand (513) is snapped into the connecting frame (512). The mechanical nozzle (514) is snapped into the stand (513). The input end of the mechanical nozzle (514) is snapped into the delivery pipe (515). The conveying assembly (52) includes a drawer (521), a bracket (522), a sieve plate (523), a bend (524), and a pump (525). The drawer (521) is slidably connected inside the outer casing (1). The bracket (522) is fixedly connected to the inner wall of the drawer (521). The sieve plate (523) is laid on the inner side of the bracket (522). The bend (524) is snapped to the output end of the drawer (521). The pump (525) is fixedly connected to the rear side of the outer casing (1).

4. The processing apparatus for titanium alloy parts according to claim 3, characterized in that: The other end of the bend (524) is snapped into the input end of the pump (525), and the other end of the delivery pipe (515) is snapped into the input end of the pump (525).

5. The processing apparatus for titanium alloy parts according to claim 4, characterized in that: The internal parts of the drawer (521), the bend (524), the pump (525), the conveying pipe (515), and the mechanical nozzle (514) are interconnected, and the sieve plate (523) is made of breathable mesh.

6. The processing apparatus for titanium alloy parts according to claim 5, characterized in that: The clamping mechanism (4) is located on the front side of the mechanical nozzle (514), and the two do not contact each other.