CN114618945A

CN114618945A - Mold for machining thin-wall curved surface part and working method thereof

Info

Publication number: CN114618945A
Application number: CN202210264235.6A
Authority: CN
Inventors: 覃佐兴
Original assignee: Suzhou Haiqiang Machinery Co ltd
Current assignee: Suzhou Haiqiang Machinery Co ltd
Priority date: 2022-03-17
Filing date: 2022-03-17
Publication date: 2022-06-14

Abstract

The invention belongs to the field of processing dies; the die comprises a frame body (100), a camera (110), a control panel (120), a lower die assembly (200), a bottom plate (210), a workbench (220), a bottom die (230), a forming space (240), a limiting column (250), a pressure sensing counter (251), a double-shaft motor (260), an infrared inductor (261), a motor base (262), a motor output rod (270), an upper die assembly (300), an upper die motor (310), an upper die transmission rod (320), an upper die bottom plate (330), an upper die (340) and an upper die buffer seat (350); the processing die disclosed by the invention has the advantages of good safety, convenience in processing, high intelligent degree and high processing efficiency.

Description

Mold for machining thin-wall curved surface part and working method thereof

Technical Field

The invention belongs to the field of processing dies; in particular to a die for processing thin-wall curved surface parts and a working method thereof.

Background

In the industrial department, a large number of thin-wall parts are used as shells for saving materials and reducing weight, and the thin-wall parts have the advantages of easy forming and processing, low cost, easy batch production and the like, but the thin-wall parts are easy to deform in the forming process, so that the processing precision is difficult to ensure. Particularly, in pressure vessels in the fields of aerospace and petrochemical industry, the combined welding of the seal head and the cylinder section forms the main structure of the pressure vessel, and the structural form is widely adopted. The shape of the end socket is generally spherical or semi-ellipsoidal curved surface, the diameter is generally more than 2000mm, and the end socket is a large-scale thin-wall complex curved surface plate part. Further, the thin-wall curved surface part is a key component of carrying equipment such as rockets, airplanes, high-speed rails and automobiles, and the geometrical shape, the dimensional accuracy and the comprehensive performance of the thin-wall curved surface part directly influence the aerodynamic performance, the bearing capacity, the effective load and the service life of the equipment, such as: the bottom of the fuel tank of the carrier rocket, the skin of the airplane, the covering parts of the automobile and the like. In order to meet the requirements of new generation of carrying equipment on light weight, high reliability and higher performance, an integrated thin-wall structure with high performance is urgently required to replace the existing multi-block split tailor-welded structure. The integration of thin-wall curved parts results in more and more complex shapes and larger sizes. In order to realize light weight, light alloy materials with light weight and high strength are required to be used, so that the thin-wall curved pieces are more and more difficult to form. In order to realize the molding, special conditions such as addition of ultralow temperature media and the like are often required to be added into a mold, so that the cost is greatly increased for mold processing of thin-wall curved parts, the operation complexity is improved, the potential safety hazard is increased, and the production efficiency is reduced. Therefore, a thin-wall curved surface part processing mold which is easy to operate, good in safety performance and high in production efficiency is urgently needed to be developed.

Disclosure of Invention

Aiming at the defects, the invention discloses a die for processing thin-wall curved surface parts and a working method thereof.

The technical scheme of the invention is as follows:

a mold for processing thin-wall curved surface parts is characterized by comprising a frame body, a camera, a control panel, a lower mold assembly, a bottom plate, a workbench, a bottom mold, a forming space, a limiting column, a pressure-sensitive counter, a double-shaft motor, an infrared inductor, a motor base, a motor output rod, an upper mold assembly, an upper mold motor, an upper mold transmission rod, an upper mold bottom plate, an upper mold and an upper mold buffer seat; the frame body is a rectangular hollow frame body; the camera is arranged at the top inside the frame body; the control panel is arranged on the side of the frame body; the lower die assembly is positioned at the bottom of the interior of the frame body; the lower die assembly comprises a bottom plate, a workbench, a bottom die, a forming space, a limiting column, a pressure-sensitive counter, a double-shaft motor, an infrared inductor, a motor base and a motor output rod; the bottom plate is arranged at the bottom inside the frame body; the bottom plate is provided with the workbench; the bottom die is slidably arranged above the workbench; the bottom die is provided with an inwards concave forming space; one side of the workbench is provided with the limiting column; the top of the limiting column is provided with the pressure-sensitive counter; the double-shaft motor is arranged on one side of the bottom plate; the infrared inductor is arranged at the top of the double-shaft motor; the motor base is arranged below the double-shaft motor; the power output end of the double-shaft motor is provided with the motor output rod; one end of the motor output rod is connected with one end of the bottom die; the upper die assembly is positioned right above the lower die assembly; the upper die assembly comprises an upper die motor, an upper die transmission rod, an upper die bottom plate, an upper die and an upper die buffer seat; the upper die motor is arranged at the top outside the frame body; the upper die transmission rod is arranged below the upper die motor; the bottom of the upper die transmission rod is provided with the upper die bottom plate; the bottom surface of the upper die bottom plate is provided with the upper die; the upper die protrudes downwards and is matched with the bottom die in shape; one end of the upper die bottom plate is provided with the upper die buffer seat; the upper die buffer seat is compared with the limiting column. The infrared sensor is arranged, so that dangerous conditions can be found timely, the work can be stopped, and the safety is good.

Furthermore, one side of the bottom plate is also provided with a material receiving box. After the part is die-cast and formed, the bottom die can be automatically overturned and demoulded by the double-shaft motor to enter the material receiving box, and the automation degree is high.

Further, according to the die for processing the thin-wall curved surface part, the control panel is further provided with the liquid crystal display screen. Set up the LCD screen, the workman can be in the framework outward appearance and observe the mould behavior, improves the security performance.

Further, according to the die for processing the thin-wall curved surface part, the liquid crystal display screen is a touch screen. The touch screen is convenient and intuitive to operate.

Furthermore, according to the die for processing the thin-wall curved surface part, the infrared sensor is provided with the wireless transmitting module, and the wireless receiving module is arranged in the control panel. And the wireless module is used, so that the trouble of wiring is avoided.

Further, according to the mold for machining the thin-wall curved surface part, the control panel is provided with a computer storage device. The storage device can record the video of the camera, so that the working condition can be analyzed conveniently in the later period.

Further, above-mentioned mould is used in processing of thin wall curved surface spare part, last mould cushion socket is the rubber material. The rubber material has low cost and good buffer performance.

Further, the working method of the die for machining the thin-wall curved surface part comprises the following steps:

1) a worker places the part to be processed on the bottom die;

2) a worker leaves the frame body, controls the double-shaft motor through the control panel, pushes the output rod of the motor and further pushes the bottom die to a proper position;

3) an upper die motor is controlled through a control panel to push an upper die transmission rod to move downwards, and an upper die and a bottom die are matched to process parts; the pressure-sensitive counter is contacted with the upper die buffer seat for counting; in the working process, when the infrared sensor detects that an obstacle exists between the upper die and the lower die, an alarm signal is sent out to control the interruption of the work;

4) after the processing is finished, separating the upper die from the bottom die; the motor output rod urgently needs to push the bottom die out of the workbench rightwards, and the bottom die is rotated, so that the part falls down and is demoulded.

According to the technical scheme, the invention has the following beneficial effects: the die for processing the thin-wall curved surface part is high in integration level, small in occupied area, good in safety and provided with the camera, can be used for timely finding dangerous conditions and stopping working, and can be used for recording the working conditions of the die in the whole process; after the part is die-cast and formed, the bottom die can be automatically overturned and demoulded by the double-shaft motor to enter the material receiving box, and the automation degree is high.

Drawings

Fig. 1 is a schematic view of a mold for machining a thin-walled curved surface part according to embodiment 1;

fig. 2 is a schematic view of a mold for machining a thin-walled curved surface part according to embodiment 2;

wherein: the device comprises a frame body 100, a camera 110, a control panel 120, a liquid crystal display screen 121, a lower die assembly 200, a bottom plate 210, a workbench 220, a bottom die 230, a forming space 240, a limiting column 250, a pressure sensing counter 251, a double-shaft motor 260, an infrared inductor 261, a motor base 262, a motor output rod 270, a material receiving box 280, an upper die assembly 300, an upper die motor 310, an upper die transmission rod 320, an upper die bottom plate 330, an upper die 340 and an upper die buffer seat 350.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", and the like, indicate orientations or positional relationships based on those shown in the drawings, merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Example 1

The mold for processing a thin-wall curved surface part shown in fig. 1 comprises a frame 100, a camera 110, a control panel 120, a lower mold assembly 200, a bottom plate 210, a workbench 220, a bottom mold 230, a forming space 240, a limiting column 250, a pressure sensing counter 251, a double-shaft motor 260, an infrared inductor 261, a motor base 262, a motor output rod 270, an upper mold assembly 300, an upper mold motor 310, an upper mold transmission rod 320, an upper mold bottom plate 330, an upper mold 340 and an upper mold buffer seat 350; the frame body 100 is a rectangular hollow frame body; the camera 110 is arranged at the top inside the frame body 100; the control panel 120 is disposed at a side of the frame 100; the lower die assembly 200 is located at the bottom of the interior of the frame body 100; the lower die assembly 200 comprises a bottom plate 210, a workbench 220, a bottom die 230, a forming space 240, a limiting column 250, a pressure-sensitive counter 251, a double-shaft motor 260, an infrared inductor 261, a motor base 262 and a motor output rod 270; the bottom plate 210 is disposed at the bottom inside the frame 100; the working table 220 is arranged on the bottom plate 210; the bottom die 230 is slidably arranged above the workbench 220; the bottom die 230 is provided with an inward concave forming space 240; one side of the workbench 220 is provided with the limiting column 250; the pressure counter 251 is arranged at the top of the limiting column 250; one side of the base plate 210 is provided with the dual-axis motor 260; the infrared inductor 261 is arranged at the top of the double-shaft motor 260; the motor base 262 is arranged below the double-shaft motor 260; the power output end of the double-shaft motor 260 is provided with the motor output rod 270; one end of the motor output rod 270 is connected to one end of the bottom die 230; the upper die assembly 300 is positioned right above the lower die assembly 200; the upper die assembly 300 comprises an upper die motor 310, an upper die transmission rod 320, an upper die bottom plate 330, an upper die 340 and an upper die buffer seat 350; the upper die motor 310 is arranged on the top of the outer part of the frame body 100; the upper mold transmission rod 320 is arranged below the upper mold motor 310; the upper mold bottom plate 330 is arranged at the bottom of the upper mold transmission rod 320; the upper die 340 is arranged on the bottom surface of the upper die base plate 330; the upper die 340 protrudes downwards to fit the shape of the bottom die 230; one end of the upper mold base plate 330 is provided with the upper mold buffer seat 350; the upper die cushion 350 is aligned with the restraint posts 250.

The working method of the die for machining the thin-wall curved surface part comprises the following steps:

1, a worker places a part to be processed on the bottom die 230;

2, when the worker leaves the frame body 100, the double-shaft motor 260 is controlled by the control panel 120 to push the motor output rod 270, and further the bottom die 230 is pushed to a proper position;

3, the upper die motor 310 is controlled by the control panel 120 to push the upper die transmission rod 320 to move downwards, and the upper die 340 and the bottom die 230 are closed to process parts; the pressure sensor counter 251 is contacted with the upper die buffer seat 350 for counting; in the working process, when the infrared sensor 261 detects that an obstacle exists between the upper die and the lower die, an alarm signal is sent out to control the interruption of the work;

4, separating the upper die 340 from the bottom die 230 after finishing the processing; the motor output rod 270 is required to push the bottom mold 230 out of the workbench 220 rightwards, and the bottom mold 230 is rotated, so that the part falls down and is demoulded.

Example 2

The mold for processing a thin-wall curved surface part shown in fig. 2 comprises a frame body 100, a camera 110, a control panel 120, a lower mold assembly 200, a bottom plate 210, a workbench 220, a bottom mold 230, a forming space 240, a limiting column 250, a pressure sensing counter 251, a double-shaft motor 260, an infrared inductor 261, a motor base 262, a motor output rod 270, an upper mold assembly 300, an upper mold motor 310, an upper mold transmission rod 320, an upper mold bottom plate 330, an upper mold 340 and an upper mold buffer seat 350; the frame body 100 is a rectangular hollow frame body; the camera 110 is arranged at the top inside the frame body 100; the control panel 120 is disposed at a side of the frame 100; the lower die assembly 200 is located at the bottom of the interior of the frame body 100; the lower die assembly 200 comprises a bottom plate 210, a workbench 220, a bottom die 230, a forming space 240, a limiting column 250, a pressure sensing counter 251, a double-shaft motor 260, an infrared inductor 261, a motor base 262 and a motor output rod 270; the bottom plate 210 is disposed at the bottom inside the frame body 100; the working table 220 is arranged on the bottom plate 210; the bottom die 230 is slidably arranged above the workbench 220; the bottom die 230 is provided with an inward concave forming space 240; one side of the workbench 220 is provided with the limiting column 250; the pressure counter 251 is arranged at the top of the limiting column 250; the dual-axis motor 260 is disposed at one side of the base plate 210; the infrared inductor 261 is arranged at the top of the double-shaft motor 260; the motor base 262 is arranged below the double-shaft motor 260; the power output end of the double-shaft motor 260 is provided with the motor output rod 270; one end of the motor output rod 270 is connected to one end of the bottom die 230; the upper die assembly 300 is positioned right above the lower die assembly 200; the upper die assembly 300 comprises an upper die motor 310, an upper die transmission rod 320, an upper die bottom plate 330, an upper die 340 and an upper die buffer seat 350; the upper die motor 310 is arranged on the top of the outer part of the frame body 100; the upper mold transmission rod 320 is arranged below the upper mold motor 310; the upper mold bottom plate 330 is arranged at the bottom of the upper mold transmission rod 320; the upper die 340 is arranged on the bottom surface of the upper die base plate 330; the upper die 340 protrudes downwards to fit the shape of the bottom die 230; one end of the upper mold base plate 330 is provided with the upper mold buffer seat 350; the upper die cushion 350 is aligned with the restraint posts 250; further, a material receiving box 280 is further arranged on one side of the bottom plate 210; preferably, the control panel 120 is further provided with a liquid crystal display screen 121; in particular, the liquid crystal display screen 121 is a touch screen; further, the infrared sensor 261 is provided with a wireless transmitting module, and a wireless receiving module is arranged in the control panel 120; in particular, the control panel 120 is provided with computer storage means; preferably, the upper die cushion seat 350 is made of rubber.

1, a worker places a part to be processed on the bottom die 230;

4, separating the upper die 340 and the bottom die 230 after finishing the processing; the motor output rod 270 is required to push the bottom mold 230 out of the workbench 220 rightwards, and the bottom mold 230 is rotated, so that the part falls down and is demoulded.

The above are only preferred embodiments of the present invention, and the scope of the present invention should not be limited thereby, and all the equivalent changes and modifications made by the claims and the summary of the invention should be covered by the protection scope of the present patent application.

Claims

1. The mold for processing the thin-wall curved surface part is characterized by comprising a frame body (100), a camera (110), a control panel (120), a lower mold assembly (200), a bottom plate (210), a workbench (220), a bottom mold (230), a forming space (240), a limiting column (250), a pressure-sensitive counter (251), a double-shaft motor (260), an infrared inductor (261), a motor base (262), a motor output rod (270), an upper mold assembly (300), an upper mold motor (310), an upper mold transmission rod (320), an upper mold bottom plate (330), an upper mold (340) and an upper mold buffer seat (350); the frame body (100) is a rectangular hollow frame body; the camera (110) is arranged at the top inside the frame body (100); the control panel (120) is arranged on the side of the frame body (100); the lower die assembly (200) is positioned at the bottom of the inner part of the frame body (100); the lower die assembly (200) comprises a bottom plate (210), a workbench (220), a bottom die (230), a forming space (240), a limiting column (250), a pressure-sensitive counter (251), a double-shaft motor (260), an infrared inductor (261), a motor base (262) and a motor output rod (270); the bottom plate (210) is arranged at the bottom inside the frame body (100); the workbench (220) is arranged on the bottom plate (210); the bottom die (230) is slidably arranged above the workbench (220); the bottom die (230) is provided with an inwards concave forming space (240); one side of the workbench (220) is provided with the limiting column (250); the top of the limiting column (250) is provided with the pressure sensing counter (251); one side of the bottom plate (210) is provided with the double-shaft motor (260); the infrared inductor (261) is arranged at the top of the double-shaft motor (260); the motor base (262) is arranged below the double-shaft motor (260); the power output end of the double-shaft motor (260) is provided with the motor output rod (270); one end of the motor output rod (270) is connected with one end of the bottom die (230); the upper die assembly (300) is positioned right above the lower die assembly (200); the upper die assembly (300) comprises an upper die motor (310), an upper die transmission rod (320), an upper die bottom plate (330), an upper die (340) and an upper die buffer seat (350); the upper die motor (310) is arranged at the top of the outer part of the frame body (100); the upper die transmission rod (320) is arranged below the upper die motor (310); the bottom of the upper die transmission rod (320) is provided with the upper die bottom plate (330); the upper die (340) is arranged on the bottom surface of the upper die bottom plate (330); the upper die (340) protrudes downwards and is matched with the bottom die (230) in shape; one end of the upper die bottom plate (330) is provided with the upper die buffer seat (350); the upper die buffer seat (350) is opposite to the limit column (250).

2. The mold for machining the thin-walled curved surface part as claimed in claim 1, wherein a material receiving box (280) is further disposed on one side of the bottom plate (210).

3. The mold for machining thin-walled curved parts according to claim 1, wherein the control panel (120) is further provided with a liquid crystal display (121).

4. The mold for machining thin-walled curved parts as claimed in claim 3, wherein the liquid crystal display (121) is a touch screen.

5. The mold for machining the thin-walled curved surface part as claimed in claim 1, wherein the infrared sensor (261) is provided with a wireless transmitting module, and the control panel (120) is internally provided with a wireless receiving module.

6. The mold for machining a thin-walled curved surface part as claimed in claim 1, wherein the control panel (120) is provided with a computer storage device.

7. The mold for machining a thin-walled curved surface part as claimed in claim 1, wherein the upper die cushion seat (350) is made of rubber.

8. The method for operating a mold for machining a thin-walled curved part as claimed in any one of claims 1 to 7, comprising the steps of:

1) a worker places the part to be processed on the bottom die (230);

2) a worker leaves the frame body (100), controls the double-shaft motor (260) through the control panel (120), and pushes the motor output rod (270) to further push the bottom die (230) to a proper position;

3) an upper die motor (310) is controlled through a control panel (120), an upper die transmission rod (320) is pushed to move downwards, an upper die (340) and a bottom die (230) are matched, and part processing is carried out; the pressure sensing counter (251) is contacted with the upper die buffer seat (350) for counting; in the working process, when the infrared sensor (261) detects that an obstacle exists between the upper die and the lower die, an alarm signal is sent out to control the interruption of the work;

4) after the processing is finished, separating the upper die (340) and the bottom die (230); the motor output rod (270) urgently needs to push the bottom die (230) out of the workbench (220) rightwards, and the bottom die (230) is rotated, so that the parts fall down and are demoulded.