CN114248116B - Production and processing device for air-cooled titanium alloy - Google Patents

Abstract

The invention discloses a production and processing device for air-cooled titanium alloy, which relates to the technical field of titanium alloy processing and comprises a workbench, a forming mechanism, a fixing mechanism, a moving mechanism, a clamping mechanism and a cutting mechanism, wherein a feeding frame is arranged on one side of the workbench, a blanking hole is formed in the other side of the workbench, a material receiving box is arranged below the other side of the workbench, the material receiving box is positioned right below the blanking hole, the forming mechanism is arranged on the workbench, the fixing mechanism is provided with two groups, the moving mechanism and the cutting mechanism are arranged between the two groups of fixing mechanisms, and the clamping mechanism is arranged at the working end of the moving mechanism; the problem of adopt the mode of artifical traction to place fashioned titanium alloy on cutting the platform among the prior art, then cut through artifical or equipment assistance multistage, the processing mode is wasted time and energy, has not only reduced machining efficiency, still needs to consume a large amount of manpowers is solved.

Description

Production and processing device for air-cooled titanium alloy

Technical Field

The invention relates to the technical field of titanium alloy processing, in particular to a production and processing device for an air-cooled titanium alloy.

Background

Titanium alloy is a structural alloy based on titanium and added with other elements, and is widely used in various fields due to the characteristics of high strength, good corrosion resistance, high heat resistance and the like.

When the titanium alloy is processed in a forming mode, the titanium alloy needs to be heated and is fixedly formed through a die, and then needs to be cut after being formed, so that the formed titanium alloy forms parts, and the formed titanium alloy is applied to other fields.

Disclosure of Invention

The embodiment of the invention provides a production and processing device for air-cooled titanium alloy, which aims to solve the problems that in the prior art, a formed titanium alloy is placed on a cutting table in a manual traction mode, then multi-section cutting is carried out by manual or equipment assistance, and the processing mode is time-consuming and labor-consuming.

The embodiment of the invention adopts the following technical scheme: the utility model provides an air-cooled production processingequipment for titanium alloy, includes workstation, forming mechanism, fixed establishment, moving mechanism, fixture and cutting mechanism, be equipped with the work or material rest on one side of workstation, the unloading hole has been seted up on the opposite side of workstation, just the below of workstation opposite side is equipped with the material receiving case, the material receiving case is located under the unloading hole, forming mechanism sets up on the workstation, just forming mechanism is located one side of material rest, fixed establishment is equipped with two sets of, and two sets of fixed establishment level sets up on the opposite side of workstation, moving mechanism and cutting mechanism set up between two sets of fixed establishment, fixture sets up on moving mechanism's work end, moving mechanism is connected with cutting mechanism.

Further, forming mechanism includes heating element, actuating assembly and connects the removal subassembly, heating element is equipped with the multiunit, multiunit heating element is the level and sets gradually one side on the workstation, actuating assembly sets up on one of them a set of heating element that is located the intermediate position, it is equipped with two sets of to connect the removal subassembly, two sets of the one end of connecting the removal subassembly is all connected with actuating assembly, two sets of the other end of connecting the removal subassembly is connected with multiunit heating element respectively.

Further, the heating assembly comprises a heating box, a heater and a die, wherein the heating box is arranged on the workbench, the heater and the die are arranged in the heating box, the die is divided into two blocks, and the two blocks of dies are respectively connected with the two groups of connecting moving assemblies.

Further, the drive assembly includes first motor, gear mount, bevel gear group, first threaded rod and fixed plate, first motor and gear mount set up on the heating cabinet, bevel gear group rotates and sets up in the gear mount, first motor is connected with the one end of bevel gear group, first threaded rod is equipped with two, two the one end of first threaded rod is connected respectively on the other both ends of bevel gear group, the fixed plate is equipped with two, two the fixed plate symmetry sets up on the both sides of heating cabinet, and every the other end of first threaded rod is all rotated and is connected on a fixed plate, two the shaft of first threaded rod is connected with a set of removal subassembly that is connected respectively.

Further, every group the connection remove the subassembly all includes movable plate, link, connecting plate, removes frame and connecting rod, it is on a movable frame all to remove the board spiro union, the connecting plate is connected with the link, the link is located one side of heating cabinet, connecting plate, removal frame and connecting rod all are equipped with a plurality of, every remove the frame and all connect on the bottom of link through a connecting plate, every remove the frame all be located one side of heating cabinet, every the one end of connecting rod all is connected on a movable frame, every the other end of connecting rod all is connected with one side of a mould.

Further, fixed establishment includes titanium alloy mount, cylinder, first gag lever post and removes the fixed block, titanium alloy mount sets up on the workstation, the cylinder sets up the top at titanium alloy mount, first gag lever post is equipped with two, two first gag lever post symmetry sets up in titanium alloy mount, remove the fixed block setting in titanium alloy mount, just remove the fixed block activity setting between two first gag lever posts.

Further, the moving mechanism comprises a first moving fixing frame, a second motor, a second threaded rod, a first moving block, a fixed connection plate and a first fixed connection frame, wherein the first moving fixing frame is arranged on one side of the workbench, the second motor is arranged on one side of the first moving fixing frame, the second threaded rod is arranged in the first moving fixing frame, the output end of the second motor is connected with the second threaded rod, the first moving block is arranged on the first moving fixing frame in a sliding mode, the first moving block is in threaded connection with the second threaded rod, one end of the fixed connection plate is arranged on the first moving block, the other end of the fixed connection plate is connected with the cutting mechanism, and the first fixed connection frame is arranged on the first moving block and is connected with the clamping mechanism.

Further, fixture includes anchor clamps rack, third motor, first connecting axle, second connecting axle and anchor clamps, the anchor clamps rack sets up on first fixed connection frame, the third motor sets up on one side of anchor clamps rack, first connecting axle rotates and sets up on the opposite side of anchor clamps rack, just the intermediate position of first connecting axle is connected with the output of third motor, second connecting axle and anchor clamps all are equipped with two, two the one end of second connecting axle rotates respectively and connects on the both ends of first connecting axle, two the anchor clamps all slide and set up on the anchor clamps rack, every the other end of second connecting axle all is connected with an anchor clamps.

Further, the cutting mechanism comprises a second movable fixing frame, a second limiting rod, a second movable block, a second fixed connecting frame and cutting equipment, wherein the second movable fixing frame is arranged on the other side of the workbench, the second limiting rod is arranged in the second movable fixing frame, the second movable block is arranged on the second movable fixing frame in a sliding mode, the second movable block is movably connected with the second limiting rod, the second movable block is connected with the other end of the fixed connecting plate, the second fixed connecting frame is arranged on the second movable block, the cutting equipment is arranged on the second fixed connecting frame, and the working end of the cutting equipment corresponds to the titanium alloy between the two groups of the fixed mechanisms.

The technical scheme adopted by the embodiment of the invention can achieve the following beneficial effects:

firstly, placing titanium alloy on an upper material rack, pulling out one end of the titanium alloy and extending the titanium alloy into a forming mechanism, heating and forming the titanium alloy through the forming mechanism, and after forming, pulling one end of the titanium alloy between two groups of fixing mechanisms through the cooperation of a moving mechanism and a clamping mechanism, wherein one group of fixing mechanisms is used for fixing the titanium alloy at one end of the forming mechanism, the other group of fixing mechanisms is used for cutting the titanium alloy through cooperation of the clamping mechanism and a cutting mechanism, and after cutting, a section of titanium alloy part falls into a material receiving box from a blanking hole, so that the forming cutting processing operation of the titanium alloy is completed; according to the invention, the formed titanium alloy can be fixedly pulled and cut through the cooperation of the fixing mechanism, the moving mechanism, the clamping mechanism and the cutting mechanism, so that the problems that in the prior art, the formed titanium alloy is placed on the cutting table in a manual pulling mode, then the multi-section cutting is carried out by manual or equipment assistance, the processing mode is time-consuming and labor-consuming, the processing efficiency is reduced, and a large amount of manpower is consumed are solved.

And secondly, the first moving block can drive the second moving block to synchronously move on the second moving fixing frame during movement through the connection of the second moving block and the fixed connecting plate, so that the clamping mechanism and the cutting equipment can synchronously move, the cutting position of the cutting equipment is not deviated every time, and the practicability is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

FIG. 1 is a schematic perspective view of a first angle of the present invention;

FIG. 2 is a schematic perspective view of a second angle of the present invention;

FIG. 3 is a schematic perspective view of a heating assembly of the present invention;

FIG. 4 is an enlarged view of FIG. 3 at A;

FIG. 5 is a schematic view of a partial structure of the present invention;

FIG. 6 is an enlarged view at B in FIG. 5;

fig. 7 is a schematic perspective view of a clamping mechanism in the present invention.

Reference numerals: the working table 1, the loading frame 11, the discharging hole 12, the material receiving box 13, the forming mechanism 2, the heating assembly 21, the heating box 211, the heater 212, the mold 213, the driving assembly 22, the first motor 221, the gear fixing frame 222, the bevel gear group 223, the first threaded rod 224, the fixing plate 225, the connection moving assembly 23, the moving plate 231, the connecting frame 232, the connecting plate 233, the moving frame 234, the connecting rod 235, the fixing mechanism 3, the titanium alloy fixing frame 31, the cylinder 32, the first limit rod 33, the moving fixing block 34, the moving mechanism 4, the first moving fixing frame 41, the second motor 42, the second threaded rod 43, the first moving block 44, the fixing connecting plate 45, the first fixing connecting frame 46, the clamping mechanism 5, the clamp placing frame 51, the third motor 52, the first connecting shaft 53, the second connecting shaft 54, the clamp 55, the cutting mechanism 6, the second moving fixing frame 61, the second limit rod 62, the second moving block 63, the second fixing connecting frame 64, and the cutting device 65.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to specific embodiments of the present invention and corresponding drawings. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The following describes in detail the technical solutions provided by the embodiments of the present invention with reference to the accompanying drawings.

Referring to fig. 1-7, an embodiment of the invention provides a production and processing device for an air-cooled titanium alloy, which comprises a workbench 1, a forming mechanism 2, a fixing mechanism 3, a moving mechanism 4, a clamping mechanism 5 and a cutting mechanism 6, wherein a feeding frame 11 is arranged on one side of the workbench 1, a blanking hole 12 is formed in the other side of the workbench 1, a material receiving box 13 is arranged below the other side of the workbench 1, the material receiving box 13 is positioned right below the blanking hole 12, the forming mechanism 2 is arranged on the workbench 1, the forming mechanism 2 is positioned on one side of the feeding frame 11, two groups of fixing mechanisms 3 are arranged, two groups of fixing mechanisms 3 are horizontally arranged on the other side of the workbench 1, the moving mechanism 4 and the cutting mechanism 6 are arranged between the two groups of fixing mechanisms 3, the clamping mechanism 5 is arranged on the working end of the moving mechanism 4, and the moving mechanism 4 is connected with the cutting mechanism 6. In the invention, titanium alloy is placed on an upper material frame 11, one end of the titanium alloy is pulled out and extends into a forming mechanism 2, the titanium alloy is heated and formed through the forming mechanism 2, one end of the titanium alloy is pulled between two groups of fixing mechanisms 3 through the cooperation of a moving mechanism 4 and a clamping mechanism 5 after the forming, one group of fixing mechanisms 3 are used for fixing the titanium alloy at one end of the forming mechanism 2, the other group of fixing mechanisms 3 are used for cutting the titanium alloy through cooperation of the clamping mechanism 5 and a cutting mechanism 6, and after the cutting, a section of titanium alloy part falls into a material receiving box 13 from a blanking hole 12, so that the forming cutting processing operation of the titanium alloy is completed; according to the invention, the formed titanium alloy can be fixedly pulled and cut through the cooperation of the fixing mechanism 3, the moving mechanism 4, the clamping mechanism 5 and the cutting mechanism 6, so that the problems that in the prior art, the formed titanium alloy is placed on a cutting table in a manual pulling mode, then multi-section cutting is carried out by manual or equipment assistance, the processing mode is time-consuming and labor-consuming, the processing efficiency is reduced, and a large amount of manpower is consumed can be solved.

Specifically, referring to fig. 3-4, the forming mechanism 2 includes a heating assembly 21, a driving assembly 22 and a connection moving assembly 23, where the heating assembly 21 is provided with multiple groups, multiple groups of heating assemblies 21 are horizontally and sequentially arranged on one side of the workbench 1, the driving assembly 22 is arranged on one group of heating assemblies 21 located at the middle position, the connection moving assembly 23 is provided with two groups, one ends of the connection moving assembly 23 are connected with the driving assembly 22, and the other ends of the connection moving assembly 23 are respectively connected with the multiple groups of heating assemblies 21. In the invention, the titanium alloy positioned in the heating component 21 can be heated and molded through the heating component 21, and the two groups of connecting and moving components 23 can relatively move through the driving component 22, so that the two groups of connecting and moving components 23 drive the heating component 21 to move, and the heating component 21 is used for fixing the titanium alloy.

Specifically, referring to fig. 3-4, the heating assembly 21 includes a heating box 211, a heater 212 and a mold 213, the heating box 211 is disposed on the table 1, the heater 212 and the mold 213 are both disposed in the heating box 211, the mold 213 is divided into two pieces, and the two pieces of the mold 213 are respectively connected with the two sets of connection moving assemblies 23. In the present invention, the heater 212 in the heating box 211 is used for heating, and the mold 213 in the heating box 211 can be combined or separated by the connection with the connection moving assembly 23, so that the mold 213 can be closed with the titanium alloy, and the mold 213 can be molded with the temperature rise.

Specifically, referring to fig. 3-4, the driving assembly 22 includes a first motor 221, a gear fixing frame 222, a bevel gear set 223, a first threaded rod 224 and a fixing plate 225, where the first motor 221 and the gear fixing frame 222 are disposed on the heating box 211, the bevel gear set 223 is rotatably disposed in the gear fixing frame 222, the first motor 221 is connected with one end of the bevel gear set 223, two first threaded rods 224 are disposed, one ends of the two first threaded rods 224 are respectively connected with the other ends of the bevel gear set 223, two fixing plates 225 are disposed symmetrically on two sides of the heating box 211, and the other end of each first threaded rod 224 is rotatably connected with one fixing plate 225, and the shafts of the two first threaded rods 224 are respectively connected with one set of connecting moving assemblies 23. In the present invention, the bevel gear set 223 is driven by the first motor 221 to rotate, and the bevel gear set 223 drives the two first threaded rods 224 to rotate when rotating, and the two first threaded rods 224 drive the two sets of connecting moving components 23 to move relatively.

Specifically, referring to fig. 3-4, each group of the connection moving assemblies 23 includes a moving plate 231, a connecting frame 232, a connecting plate 233, a moving frame 234 and a connecting rod 235, the moving plate 231 is screwed on the first threaded rod 224, the connecting plate 233 is connected with the connecting frame 232, the connecting frame 232 is located at one side of the heating box 211, the connecting plate 233, the moving frame 234 and the connecting rod 235 are provided with a plurality of pieces, each moving frame 234 is connected to the bottom end of the connecting frame 232 through one connecting plate 233, each moving frame 234 is located at one side of the heating box 211, one end of each connecting rod 235 is connected to one moving frame 234, and the other end of each connecting rod 235 is connected to one side of one mold 213. The screw connection between the two moving plates 231 and the two first threaded rods 224 can enable the first threaded rods 224 to drive the two connecting frames 232 to move relatively when rotating, so that the connecting frames 232 drive the connecting plates 233 to enable the moving frames 234 and the connecting rods 235 to drive the mold 213 to be closed or opened.

Specifically, referring to fig. 6, the fixing mechanism 3 includes a titanium alloy fixing frame 31, an air cylinder 32, a first limit rod 33 and a movable fixing block 34, the titanium alloy fixing frame 31 is disposed on the workbench 1, the air cylinder 32 is disposed above the titanium alloy fixing frame 31, two first limit rods 33 are disposed symmetrically in the titanium alloy fixing frame 31, the movable fixing block 34 is disposed in the titanium alloy fixing frame 31, and the movable fixing block 34 is movably disposed between the two first limit rods 33. In the present invention, the titanium alloy passes through the titanium alloy holder 31 after being molded, and the movable fixing block 34 can fix the titanium alloy located in the titanium alloy holder 31 by driving the cylinder 32.

Specifically, referring to fig. 5, the moving mechanism 4 includes a first moving mount 41, a second motor 42, a second threaded rod 43, a first moving block 44, a fixed connection plate 45, and a first fixed connection frame 46, where the first moving mount 41 is disposed on one side of the workbench 1, the second motor 42 is disposed on one side of the first moving mount 41, the second threaded rod 43 is disposed in the first moving mount 41, an output end of the second motor 42 is connected with the second threaded rod 43, the first moving block 44 is slidably disposed on the first moving mount 41, and the first moving block 44 is screwed with the second threaded rod 43, one end of the fixed connection plate 45 is disposed on the first moving block 44, the other end of the fixed connection plate 45 is connected with the cutting mechanism 6, and the first fixed connection frame 46 is disposed on the first moving block 44, and the first fixed connection frame 46 is connected with the clamping mechanism 5.

Specifically, referring to fig. 7, the clamping mechanism 5 includes a clamp placing frame 51, a third motor 52, a first connecting shaft 53, a second connecting shaft 54 and a clamp 55, where the clamp placing frame 51 is disposed on the first fixed connecting frame 46, the third motor 52 is disposed on one side of the clamp placing frame 51, the first connecting shaft 53 is rotatably disposed on the other side of the clamp placing frame 51, and the middle position of the first connecting shaft 53 is connected with the output end of the third motor 52, two second connecting shafts 54 and two clamps 55 are respectively disposed, one ends of the two second connecting shafts 54 are respectively rotatably connected to two ends of the first connecting shaft 53, two clamps 55 are respectively slidably disposed on the clamp placing frame 51, and the other end of each second connecting shaft 54 is connected with one clamp 55. In the invention, the first connecting shaft 53 can be driven to rotate by the third motor 52, and the first connecting shaft 53 can drive the two second connecting shafts 54 to synchronously rotate when rotating, so that the two second connecting shafts 54 drive the two clamps 55 to relatively move on the clamp placing frame 51, the two clamps 55 can clamp the titanium alloy, and the clamps 55 drive the titanium alloy to move by the cooperation of the moving mechanism 4.

Specifically, referring to fig. 5, the cutting mechanism 6 includes a second moving fixing frame 61, a second limiting rod 62, a second moving block 63, a second fixed connecting frame 64 and a cutting device 65, the second moving fixing frame 61 is disposed on the other side of the workbench 1, the second limiting rod 62 is disposed in the second moving fixing frame 61, the second moving block 63 is slidably disposed on the second moving fixing frame 61, the second moving block 63 is movably connected with the second limiting rod 62, the second moving block 63 is connected with the other end of the fixed connecting plate 45, the second fixed connecting frame 64 is disposed on the second moving block 63, the cutting device 65 is disposed on the second fixed connecting frame 64, and the working end of the cutting device 65 corresponds to the titanium alloy located between the two groups of fixed mechanisms 3. In the invention, the connection between the second moving block 63 and the fixed connecting plate 45 can enable the first moving block 44 to drive the second moving block 63 to synchronously move on the second moving fixing frame 61 during moving, so that the clamping mechanism 5 and the cutting device 65 can synchronously move, and the cutting position of the cutting device 65 cannot deviate each time.

The foregoing is merely exemplary of the present invention and is not intended to limit the present invention. Various modifications and variations of the present invention will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the invention are to be included in the scope of the claims of the present invention.

Claims (3)

1. The production and processing device for the air-cooled titanium alloy is characterized by comprising a workbench (1), a forming mechanism (2), a fixing mechanism (3), a moving mechanism (4), a clamping mechanism (5) and a cutting mechanism (6), wherein a feeding frame (11) is arranged on one side of the workbench (1), a discharging hole (12) is formed in the other side of the workbench (1), a material receiving box (13) is arranged below the other side of the workbench (1), the material receiving box (13) is positioned right below the discharging hole (12), the forming mechanism (2) is arranged on the workbench (1), the forming mechanism (2) is positioned on one side of the feeding frame (11), two groups of fixing mechanisms (3) are arranged, the two groups of fixing mechanisms (3) are horizontally arranged on the other side of the workbench (1), the moving mechanism (4) and the cutting mechanism (6) are arranged between the two groups of fixing mechanisms (3), and the clamping mechanism (5) is arranged on the working end of the moving mechanism (4), and the moving mechanism (4) is connected with the cutting mechanism (6). The forming mechanism (2) comprises heating assemblies (21), driving assemblies (22) and connecting moving assemblies (23), wherein a plurality of groups of heating assemblies (21) are arranged, the plurality of groups of heating assemblies (21) are horizontally arranged on one side of the workbench (1) in sequence, the driving assemblies (22) are arranged on one group of heating assemblies (21) positioned in the middle position, the connecting moving assemblies (23) are provided with two groups, one ends of the two groups of connecting moving assemblies (23) are connected with the driving assemblies (22), and the other ends of the two groups of connecting moving assemblies (23) are respectively connected with the plurality of groups of heating assemblies (21); the heating assembly (21) comprises a heating box (211), a heater (212) and a die (213), wherein the heating box (211) is arranged on the workbench (1), the heater (212) and the die (213) are arranged in the heating box (211), the die (213) is divided into two blocks, and the two blocks of dies (213) are respectively connected with the two groups of connecting moving assemblies (23); the driving assembly (22) comprises a first motor (221), a gear fixing frame (222), a bevel gear set (223), a first threaded rod (224) and a fixing plate (225), wherein the first motor (221) and the gear fixing frame (222) are arranged on the heating box (211), the bevel gear set (223) is rotatably arranged in the gear fixing frame (222), the first motor (221) is connected with one end of the bevel gear set (223), two first threaded rods (224) are arranged, one ends of the two first threaded rods (224) are respectively connected to the other two ends of the bevel gear set (223), two fixing plates (225) are arranged, the two fixing plates (225) are symmetrically arranged on two sides of the heating box (211), the other end of each first threaded rod (224) is rotatably connected to one fixing plate (225), and the rod bodies of the two first threaded rods (224) are respectively connected with one group of connecting moving assemblies (23); each group of connecting moving assemblies (23) comprises a moving plate (231), a connecting frame (232), a connecting plate (233), moving frames (234) and connecting rods (235), wherein the moving plate (231) is connected to a first threaded rod (224) in a threaded mode, the connecting frame (232) is connected with the moving plate (231), the connecting plate (233) is connected with the connecting frame (232), the connecting frame (232) is located at one side of a heating box (211), the connecting plate (233), the moving frames (234) and the connecting rods (235) are all provided with a plurality of connecting plates, each moving frame (234) is connected to the bottom end of the connecting frame (232) through one connecting plate (233), each moving frame (234) is located at one side of one heating box (211), one end of each connecting rod (235) is connected to one side of one die (213), and the other end of each connecting rod (235) is connected to one side of one die (213); the moving mechanism (4) comprises a first moving fixing frame (41), a second motor (42), a second threaded rod (43), a first moving block (44), a fixed connecting plate (45) and a first fixed connecting frame (46), wherein the first moving fixing frame (41) is arranged on one side of the workbench (1), the second motor (42) is arranged on one side of the first moving fixing frame (41), the second threaded rod (43) is arranged in the first moving fixing frame (41), the output end of the second motor (42) is connected with the second threaded rod (43), the first moving block (44) is arranged on the first moving fixing frame (41) in a sliding mode, the first moving block (44) is in threaded connection with the second threaded rod (43), one end of the fixed connecting plate (45) is arranged on the first moving block (44), the other end of the fixed connecting plate (45) is connected with the cutting mechanism (6), and the first fixed connecting frame (46) is arranged on the first moving block (44), and the first fixed connecting frame (46) is connected with the clamping mechanism (5); the cutting mechanism (6) comprises a second movable fixing frame (61), a second limiting rod (62), a second movable block (63), a second fixed connecting frame (64) and cutting equipment (65), the second movable fixing frame (61) is arranged on the other side of the workbench (1), the second limiting rod (62) is arranged in the second movable fixing frame (61), the second movable block (63) is slidably arranged on the second movable fixing frame (61), the second movable block (63) is movably connected with the second limiting rod (62), the second movable block (63) is connected with the other end of the fixed connecting plate (45), the second fixed connecting frame (64) is arranged on the second movable block (63), the cutting equipment (65) is arranged on the second fixed connecting frame (64), and the working end of the cutting equipment (65) corresponds to the titanium alloy between the two groups of fixing mechanisms (3).

2. The production and processing device for the air-cooled titanium alloy according to claim 1, wherein the fixing mechanism (3) comprises a titanium alloy fixing frame (31), an air cylinder (32), first limiting rods (33) and movable fixing blocks (34), the titanium alloy fixing frame (31) is arranged on the workbench (1), the air cylinder (32) is arranged above the titanium alloy fixing frame (31), the first limiting rods (33) are arranged in two, the two first limiting rods (33) are symmetrically arranged in the titanium alloy fixing frame (31), the movable fixing blocks (34) are connected with piston rods of the air cylinder (32), and the movable fixing blocks (34) are movably arranged between the two first limiting rods (33).

3. The production and processing device for the air-cooled titanium alloy according to claim 1, wherein the clamping mechanism (5) comprises a clamp placing frame (51), a third motor (52), a first connecting shaft (53), a second connecting shaft (54) and clamps (55), the clamp placing frame (51) is arranged on the first fixed connecting frame (46), the third motor (52) is arranged on one side of the clamp placing frame (51), the first connecting shaft (53) is rotatably arranged on the other side of the clamp placing frame (51), the middle position of the first connecting shaft (53) is connected with the output end of the third motor (52), two second connecting shafts (54) and the clamps (55) are respectively arranged, one ends of the two second connecting shafts (54) are respectively rotatably connected to two ends of the first connecting shaft (53), the two clamps (55) are respectively slidably arranged on the clamp placing frame (51), and the other end of each second connecting shaft (54) is connected with one clamp (55).

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