CN118064702B - Processing method of thermoplastically deformable Ti6242S high-temperature titanium alloy wire rod - Google Patents

Abstract

The invention relates to the technical field of titanium material manufacturing, and discloses a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire, which comprises the following steps: the titanium alloy wire is plugged into the heating pipe, and the heating device is started to heat the titanium alloy wire inside; the heated titanium alloy wire needs to be subjected to precipitation strengthening, and the surface of the titanium alloy wire is pressed, so that the soluble group part in the titanium alloy wire is completely remained in solid solution; the surface of the titanium alloy wire is cooled, so that the condition that cold air cannot flow into the bottom of the titanium alloy wire due to the fact that the bottom of the titanium alloy wire is covered by the clamping device is prevented, and the outer surface of the titanium alloy wire cannot be comprehensively cooled. Through being provided with compression subassembly, the expansion ring in the atmospheric pressure drive compression dish stretches out to the outside, can inwards shrink to press the titanium alloy in the standing groove after the expansion ring stretches out to the outside to all remain in solid solution with the soluble group part in the titanium alloy wire rod.

Description

Processing method of thermoplastically deformable Ti6242S high-temperature titanium alloy wire rod

Technical Field

The invention relates to the technical field of titanium material manufacturing, in particular to a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire.

Background

In the current domestic market, the manufacturing mode of the titanium wire is mainly a hole die drawing process, the process mainly solves the problems of high energy consumption, low efficiency, small single weight, low yield, no pollution to the environment caused by alkaline pickling and the like, and the conventional hole die drawing process is difficult to meet the market demands along with the continuous increase of the market demands on the titanium wire and the gradual improvement of the quality demands, and based on the situation, the bright drawing preparation process of the large single weight titanium and titanium alloy is achieved;

the patent application with the application number 202010054285.2 discloses a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire, which comprises the steps of adopting a blank preparation technology, a multimode drawing technology and a continuous annealing technology under the protection of inert gas for processing a rod blank to finally obtain the titanium alloy wire, and compared with the titanium alloy wire prepared by adopting the traditional hole die drawing technology;

However, this patent also has a disadvantage that when the titanium alloy wire is subjected to solution treatment and then is kept at an appropriate temperature for a sufficient time, if the soluble component is kept partially in solid solution, it is necessary to keep the titanium alloy wire for a relatively long period of time, so that the working efficiency is lowered, and in this case, a method for processing a thermoplastically deformable Ti6242S high temperature titanium alloy wire is specifically proposed.

Disclosure of Invention

The invention aims to provide a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire rod, which aims to solve the problems in the prior art.

In order to solve the technical problems, the invention provides the following technical scheme: a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire comprises the following steps:

S1, plugging the titanium alloy wire into the heating pipe, and starting the heating device to heat the titanium alloy wire inside.

S2, carrying out precipitation strengthening on the heated titanium alloy wire, and pressing the surface of the titanium alloy wire to ensure that the soluble group part in the titanium alloy wire is completely remained in solid solution.

S3, cooling treatment is carried out on the surface of the titanium alloy wire, so that the situation that cold air cannot flow into the bottom of the titanium alloy wire due to the fact that the bottom of the titanium alloy wire is covered by the clamping device is prevented, and therefore the outer surface of the titanium alloy wire cannot be comprehensively cooled.

According to the above technical scheme, the one end fixedly connected with work box of heating pipe, the one end of transmission pipe runs through the surface of work box, the one end that the work box was kept away from to the heating pipe rotates and is connected with the protection casing, the bottom fixedly connected with bottom plate of work box, the fixedly connected with cooling tank of surface of bottom plate, the left side fixedly connected with transmission pipe of cooling tank, the one end and the right side fixedly connected with of work box of cooling tank are kept away from to the transmission pipe still include:

the compression assembly comprises a movable disc fixedly connected with the left side of a working box, the right side of the movable disc is fixedly connected with the compression disc, one end of the compression disc, which is far away from the movable disc, penetrates through the surface of the working box, the bottom of the inner wall of the movable disc is connected with a connecting column through a sliding block, one end of the connecting column, which is far away from the inner wall of the movable disc, is fixedly connected with a pulling block, the surface of the connecting column is fixedly connected with a compression ring, the bottom of the inner wall of the compression disc is fixedly connected with a transmission rod, the surface of the transmission rod is provided with a placing groove, the right side of the compression disc is connected with a telescopic ring in a sliding manner, the bottom of the inner wall of a heating pipe is provided with a solid melting assembly, and the right side of the inner wall of the working box is provided with a cooling assembly, and air pressure is generated in the compression ring and discharged into the compression disc from the connecting column.

According to the technical scheme, the cooling assembly comprises a conveying pipe, one end of the conveying pipe is fixedly connected with the right side of the inner wall of the working box, one end of the conveying pipe, which is far away from the right side of the inner wall of the working box, is fixedly connected with a connecting box, the surface of the connecting box is slidably connected with a telescopic arm, one end of the telescopic arm, which is far away from the connecting box, is fixedly connected with a flitch, and a power device in the connecting box is started to extend the telescopic arm outwards.

According to the technical scheme, solid solution subassembly includes the flexible piece, the inner wall bottom fixed connection of flexible piece and heating pipe, the right side fixedly connected with telescopic link of flexible piece, the surface sliding connection of telescopic link has the cladding piece, the inner wall fixedly connected with flexible membrane of cladding piece, the inner wall fixedly connected with absorption ball of flexible membrane, the inside heat of absorption ball can make flexible membrane surface temperature rise sharply.

According to the technical scheme, the cooling assembly further comprises a pushing ring, the pushing ring is fixedly connected with the bottom of the inner wall of the flitch, the top of the pushing ring is slidably connected with a cooling column, the top of the cooling column is in surface contact with the top of the inner wall of the flitch, two sides of the cooling column are fixedly connected with a spraying cavity, the inner wall of the flitch is fixedly connected with a connecting frame, one end of the connecting frame, which is far away from the flitch, is fixedly connected with a movable ring, the upper side and the lower side of the movable ring are slidably connected with cleaning columns, one end of the movable ring, which is far away from the cleaning columns, is fixedly connected with an adsorption cavity, the left side of the movable ring is fixedly connected with a pressure ring, the upper side and the lower side of the pressure ring are fixedly connected with telescopic pipes, an air pressure groove is formed in the top of the adsorption cavity, the compression film is arranged at the top of the air pressure groove, the bottom of the compression film is fixedly connected with a telescopic ball, and the air conditioner can be outwards expanded after flowing into the inside the movable ring.

According to the technical scheme, solid subassembly that melts still includes the expansion tank, the top of expansion tank and the bottom sliding connection of transmission pole, the both sides fixedly connected with linking arm of expansion tank, the one end fixedly connected with folding piece of expansion tank is kept away from to the linking arm, the fixed surface of folding piece is connected with the slip pipe, the both sides slotted hole department sliding connection of slip pipe and transmission pole, the top fixedly connected with fastening membrane of folding piece, the inner wall fixedly connected with adsorption disc of folding piece adsorbs the fastening membrane fixed to the titanium alloy wire surface through the adsorption disc.

According to the technical scheme, the number of the connecting arms is two, the two connecting arms are symmetrically arranged on two sides of the telescopic box by taking the central line of the telescopic box as a symmetrical axis, and the folding blocks are driven to slide through the connecting arms.

According to the technical scheme, the number of the telescopic blocks is two, the two telescopic blocks are symmetrically arranged at the bottom of the inner wall of the heating pipe by taking the central line of the heating pipe as a symmetrical axis, and the power device in the telescopic blocks is remotely started to drive the cladding blocks to slide on the surface of the telescopic rod.

Compared with the prior art, the invention provides a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire, which has the following beneficial effects:

1. According to the invention, the compression assembly is arranged, when the connecting column rotates, the compression ring on the surface of the connecting column generates pressure, so that air pressure generated in the compression ring is discharged into the compression disc from the connecting column, the air pressure drives the telescopic ring in the compression disc to extend outwards, and when the telescopic ring extends outwards, the telescopic ring contracts inwards to press the titanium alloy in the placing groove, so that the soluble group part in the titanium alloy wire is fully reserved in solid solution.

2. According to the invention, the cooling assembly is arranged, the inside of the cleaning column is outwards extended into the placing grooves on the upper side and the lower side of the transmission rod after being subjected to cold air, the titanium alloy wire bottom in the placing groove is inserted into the adsorption cavity, and finally the cold air sprayed out of the opening of the adsorption cavity flows into the placing groove, so that the bottom of the titanium alloy wire is cooled, and the situation that the cold air cannot flow into the bottom of the titanium alloy wire due to the fact that the bottom of the titanium alloy wire is covered by the inner wall of the placing groove is prevented, and therefore the outer surface of the titanium alloy wire cannot be comprehensively cooled is avoided.

3. According to the invention, the solid melting assembly is arranged, the fastening film is used for adsorbing and fixing the surface of the titanium alloy wire rod through the adsorption disc, the fastening film can be expanded outwards to wrap the titanium alloy wire rod with different volumes after being pressed downwards, the titanium alloy wire rod is driven to slide in the placing groove through the expansion box, and finally the heating device in the heating pipe is started to enable the temperature in the heating pipe to rise to heat the titanium alloy wire rod.

4. According to the invention, the cladding block is arranged, when the cladding block slides, the telescopic film in the cladding block can be contacted with the titanium alloy wire in the placing groove, the surface of the titanium alloy wire is uniformly heated through the telescopic film, and the component is arranged, so that the surface of the titanium alloy wire can be uniformly heated.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal cross-sectional structure of the work box of the present invention;

FIG. 3 is a schematic cross-sectional view of a compression ring of the present invention;

FIG. 4 is a schematic elevational view of the delivery tube of the present invention;

FIG. 5 is an enlarged schematic view of portion A of FIG. 4;

FIG. 6 is a schematic left-hand structural view of the connector of the present invention;

FIG. 7 is a schematic elevational view of the adsorption chamber of the present invention;

FIG. 8 is a schematic elevational view of the cladding block of the present invention;

fig. 9 is a schematic elevational view of the bellows of the present invention.

In the figure: 1. a bottom plate; 2. a cooling box; 3. a transmission tube; 4. a working box; 5. heating pipes; 6. a protective cover; 7. a compression assembly; 701. a movable plate; 702. a connecting column; 703. a compression ring; 704. pulling the block; 705. a compression plate; 706. a placement groove; 707. a transmission rod; 708. a telescopic ring; 8. a cooling assembly; 801. a delivery tube; 802. a connection box; 803. a telescoping arm; 804. pasting a board; 805. a cooling column; 806. pushing the ring; 807. a spray chamber; 808. a connecting frame; 809. a movable ring; 810. cleaning the column; 811. an adsorption chamber; 812. a pressure ring; 813. a telescopic tube; 814. a gas lance; 815. an air pressure tank; 816. a telescopic ball; 817. compressing the membrane; 9. a solid melting assembly; 901. a telescopic block; 902. a telescopic rod; 903. a cladding block; 904. a flexible membrane; 905. an absorbent ball; 906. a sliding tube; 907. folding the block; 908. fastening a film; 909. an adsorption plate; 910. a connecting arm; 911. a telescopic box.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. 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.

Referring to fig. 1-3, the present invention provides the following technical solutions: a processing method of a thermoplastically deformable Ti6242S high-temperature titanium alloy wire comprises the following steps:

S1, plugging the titanium alloy wire into the heating pipe 5, and starting the heating device to heat the titanium alloy wire inside.

S2, carrying out precipitation strengthening on the heated titanium alloy wire, and pressing the surface of the titanium alloy wire to ensure that the soluble group part in the titanium alloy wire is completely remained in solid solution.

S3, cooling treatment is carried out on the surface of the titanium alloy wire, so that the situation that cold air cannot flow into the bottom of the titanium alloy wire due to the fact that the bottom of the titanium alloy wire is covered by the clamping device is prevented, and therefore the outer surface of the titanium alloy wire cannot be comprehensively cooled.

One end fixedly connected with work box 4 of heating pipe 5, the one end of transfer line 3 runs through the surface of work box 4, and the one end that work box 4 was kept away from to heating pipe 5 rotates and is connected with protection casing 6, the bottom fixedly connected with bottom plate 1 of work box 4, the fixedly connected with cooling tank 2 of surface of bottom plate 1, the left side fixedly connected with transfer line 3 of cooling tank 2, the one end that cooling tank 2 was kept away from to transfer line 3 and the right side fixedly connected with of work box 4 still include:

Compression subassembly 7, including with the left side fixedly connected with movable tray 701 of work box 4, the right side fixedly connected with compression tray 705 of movable tray 701, the one end that movable tray 701 was kept away from to compression tray 705 runs through the surface of work box 4, the inner wall bottom of movable tray 701 is through slider sliding connection there being spliced pole 702, the one end fixedly connected with pulling block 704 that movable tray 701 inner wall was kept away from to spliced pole 702, the fixed surface of spliced pole 702 is connected with compression ring 703, compression ring 703's internally mounted has the gasbag, compression tray 705's inner wall bottom fixedly connected with transfer line 707, standing groove 706 has been seted up on transfer line 707's surface, compression tray 705's right side sliding connection has flexible ring 708, the slotted hole has been seted up to flexible ring 708's inner wall, the inner wall bottom of heating pipe 5 is provided with solid and melts subassembly 9, the inner wall right side of work box 4 is provided with cooling module 8.

The first embodiment works in the following manner: the protective cover 6 is lifted, the interior of the heating pipe 5 is leaked out, the titanium alloy wire is plugged into the placing groove 706 on the surface of the transmission rod 707, after the titanium alloy wire is solid-dissolved and is sent into the interior of the working box 4 through the transmission rod 707, the titanium alloy wire is moved into the interior of the telescopic ring 708, the pulling block 704 is pulled to drive the connecting column 702 at the bottom of the connecting column 702 to rotate on the inner wall of the movable disc 701, when the connecting column 702 rotates, the pressure is generated on the compressing ring 703 on the surface of the connecting column, so that air pressure is generated in the compressing ring 703 and is discharged into the compressing disc 705 from the connecting column 702, the air pressure drives the telescopic ring 708 in the compressing disc 705 to extend outwards, and after the telescopic ring 708 extends outwards, the telescopic ring 708 contracts inwards to press the titanium alloy in the placing groove 706, and therefore the soluble group part in the titanium alloy wire is fully reserved in the solid solution.

Embodiment two: distinguishing features from the first embodiment: as shown in fig. 4-7, the cooling assembly 8 comprises a conveying pipe 801, one end of the conveying pipe 801 is fixedly connected with the right side of the inner wall of the working box 4, one end of the conveying pipe 801 far away from the right side of the inner wall of the working box 4 is fixedly connected with a connecting box 802, the surface of the connecting box 802 is slidably connected with a telescopic arm 803, and one end of the telescopic arm 803 far away from the connecting box 802 is fixedly connected with a flitch 804;

The cooling assembly 8 further comprises a pushing ring 806, the pushing ring 806 is fixedly connected with the bottom of the inner wall of the flitch 804, the top of the pushing ring 806 is slidably connected with a cooling column 805, cooling liquid is injected into the cooling column 805, the top of the cooling column 805 is in contact with the top surface of the inner wall of the flitch 804, two sides of the cooling column 805 are fixedly connected with a spray cavity 807, the inner wall of the flitch 804 is fixedly connected with a connecting frame 808, one end of the connecting frame 808 away from the flitch 804 is fixedly connected with a movable ring 809, the upper side and the lower side of the movable ring 809 are slidably connected with cleaning columns 810, one end of the cleaning columns 810 away from the movable ring 809 is fixedly connected with an adsorption cavity 811, the left side of the movable ring 809 is fixedly connected with a pressure ring 812, the upper side and the lower side of the pressure ring 812 are fixedly connected with telescopic pipes 813, an air pressure groove 815 is formed in the top of the adsorption cavity 811, the top of the adsorption cavity 811 is fixedly connected with a compression film 817, the compression film 817 is arranged at the top of the air pressure groove 815, and the bottom of the compression film 817 is fixedly connected with a telescopic ball 816.

The working mode of the second embodiment is as follows: when the titanium alloy wire is deposited and strengthened, the cooling box 2 is started to enable cold air in the cooling box to be sent into the conveying pipe 801 from the conveying pipe 3, then the cold air is discharged into the flitch 804 from the connecting box 802, the power device in the connecting box 802 is started to enable the telescopic arm 803 to be telescopic outwards, the flitch 804 is driven to move to the surface of the conveying rod 707 after the telescopic arm 803 is telescopic outwards, meanwhile, the cold air can push the cooling column 805 in the flitch 804 when being conveyed on the inner wall, the cooling column 805 can slide on the top of the pushing ring 806 after being pushed, the inner wall of the cooling column 805 is extruded through the pushing ring 806, so that cooling liquid in the cooling column 805 is sprayed out from the spraying cavity 807, the cooling liquid is sprayed out from the slotted holes in the bottom of the inner wall of the flitch 804, the cooling liquid can be uniformly distributed on the surface of the titanium alloy wire, the cooling liquid can flow into the movable ring 809 from the inner wall of the flitch 804 through the connecting frame 808, the cold air flows into the movable ring 809 to expand outwards, the cold air is sprayed out from the inside of the movable ring 809 through the outlet hole of the pressure ring 812 to cool the titanium alloy wire rod in the placing groove 706, the cold air flows into the telescopic pipe 813 from the inside of the pressure ring 812, the telescopic pipe 813 expands outwards after receiving the cold air, the telescopic pipe 813 expands outwards and stretches into the placing groove 706, the cold air flowing out from the opening of the telescopic pipe 813 can cool the position of the titanium alloy wire rod covered by the placing groove 706, meanwhile, the inside of the cleaning post 810 can extend outwards into the placing groove 706 on the upper side and the lower side of the transmission rod 707 after receiving the cold air, the titanium alloy wire rod is inserted into the bottom of the placing groove 706 through the adsorption cavity 811, and finally the cold air sprayed out from the opening of the adsorption cavity 811 flows into the placing groove 706 to cool the bottom of the titanium alloy wire rod, meanwhile, after the surface of the adsorption cavity 811 is inserted into a seam formed by the titanium alloy wire and the placing groove 706, the titanium alloy wire extrudes the surface of the compression film 817, the compression film 817 can drive the telescopic ball 816 at the bottom of the compression film 817 to impact the inside of the air pressure groove 815 after being extruded, cold air in the adsorption cavity 811 can be extruded outwards after the air pressure groove 815 is internally pressurized, and the cold air flows into the placing groove 706 through the air injection pipes 814 at two sides of the adsorption cavity 811. By providing this assembly, the bottom of the titanium alloy wire is prevented from being covered by the inner wall of the placement groove 706, which results in that cold air cannot flow into the bottom of the titanium alloy wire, and thus the outer surface of the titanium alloy wire cannot be comprehensively cooled.

Embodiment III: distinguishing features from the first embodiment: as shown in fig. 8-9, the solid melting component 9 comprises a telescopic block 901, the telescopic block 901 is fixedly connected with the bottom of the inner wall of the heating pipe 5, a telescopic rod 902 is fixedly connected to the right side of the telescopic block 901, a coating block 903 is slidably connected to the surface of the telescopic rod 902, a telescopic film 904 is fixedly connected to the inner wall of the coating block 903, an absorption ball 905 is fixedly connected to the inner wall of the telescopic film 904, and an absorption hole is formed in the surface of the absorption ball 905;

The solid-melt assembly 9 further comprises a telescopic box 911, the top of the telescopic box 911 is slidably connected with the bottom of the transmission rod 707, two sides of the telescopic box 911 are fixedly connected with connecting arms 910, one end, away from the telescopic box 911, of each connecting arm 910 is fixedly connected with a folding block 907, the surface of each folding block 907 is fixedly connected with a sliding pipe 906, the sliding pipes 906 are slidably connected with slot holes on two sides of the transmission rod 707, the top of each folding block 907 is fixedly connected with a fastening film 908, the fastening films 908 have the characteristic of internal and external expansion, and the inner wall of each folding block 907 is fixedly connected with an adsorption disc 909.

The third embodiment works in the following manner: when the titanium alloy wire is plugged into the placing groove 706, the power device in the telescopic box 911 is remotely started to drive the sliding tube 906 to slide on two sides of the transmission rod 707, after the sliding tube 906 moves to the surface of the titanium alloy wire, the fastening film 908 is pressed downwards to enable the sliding tube 906 to bend and move to the surface of the titanium alloy wire, the fastening film 908 is adsorbed and fixed on the surface of the titanium alloy wire through the adsorption disc 909, the fastening film 908 can be expanded outwards to wrap titanium alloy wires with different volumes after being pressed downwards, the titanium alloy wires are driven to slide in the placing groove 706 through the telescopic box 911, finally, the heating device in the heating tube 5 is started to enable the temperature in the heating tube 5 to rise to heat the titanium alloy wires, after the temperature in the heating tube 5 rises, the heat in the heating tube is absorbed into the inside through the absorption ball 905, the heat in the absorption ball 905 can enable the surface temperature of the telescopic film 904 to rise sharply, the power device in the remote starting telescopic block 901 drives the coating block 903 to slide on the surface of the telescopic rod 902, when the coating block 903 is pressed downwards, the titanium alloy wire in the sliding process, the telescopic film 904 in the telescopic block can be contacted with the titanium alloy wire in the placing groove 706, and finally, the temperature in the telescopic block 904 can be evenly heated, and the titanium alloy wire can be heated on the surface evenly.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The processing method of the thermoplastically deformable Ti6242S high-temperature titanium alloy wire is characterized by comprising the following steps of:

S1, plugging a titanium alloy wire into the heating pipe (5), and starting a heating device to heat the titanium alloy wire inside;

s2, carrying out precipitation strengthening on the heated titanium alloy wire, and pressing the surface of the titanium alloy wire to ensure that the soluble group part in the titanium alloy wire is completely remained in solid solution;

S3, cooling the surface of the titanium alloy wire, so that the situation that cold air cannot flow into the bottom of the titanium alloy wire due to the fact that the bottom of the titanium alloy wire is covered by the clamping device is prevented, and the outer surface of the titanium alloy wire cannot be comprehensively cooled;

One end fixedly connected with work box (4) of heating pipe (5), the surface of work box (4) is run through to the one end of heating pipe (5), the one end rotation that work box (4) was kept away from to heating pipe (5) is connected with protection casing (6), the bottom fixedly connected with bottom plate (1) of work box (4), the fixed surface of bottom plate (1) is connected with cooling box (2), the left side fixedly connected with transmission tube (3) of cooling box (2), the one end that cooling box (2) was kept away from to transmission tube (3) and the right side fixedly connected with of work box (4), still include:

Compression subassembly (7), including movable dish (701) with the left side fixed connection of work box (4), the right side fixedly connected with compression dish (705) of movable dish (701), the one end that movable dish (701) was kept away from to compression dish (705) runs through the surface of work box (4), the inner wall bottom of movable dish (701) is through slider sliding connection's spliced pole (702), the one end fixedly connected with pulling block (704) of movable dish (701) inner wall is kept away from to spliced pole (702), the fixed surface of spliced pole (702) is connected with compression ring (703), the inner wall bottom fixedly connected with transmission pole (707) of compression dish (705), standing groove (706) have been seted up on the surface of transmission pole (707), the right side sliding connection of compression dish (705) has expansion ring (708), the inner wall bottom of heating pipe (5) is provided with solid and melts subassembly (9), the inner wall right side of work box (4) is provided with cooling module (8).

2. The method for processing the thermoplastically deformable Ti6242S high temperature titanium alloy wire according to claim 1, wherein the method comprises the following steps: the cooling assembly (8) comprises a conveying pipe (801), one end of the conveying pipe (801) is fixedly connected with the right side of the inner wall of the working box (4), one end of the conveying pipe (801) away from the right side of the inner wall of the working box (4) is fixedly connected with a connecting box (802), the surface of the connecting box (802) is slidably connected with a telescopic arm (803), and one end of the telescopic arm (803) away from the connecting box (802) is fixedly connected with a flitch (804).

3. The method for processing the thermoplastically deformable Ti6242S high temperature titanium alloy wire according to claim 1, wherein the method comprises the following steps: the solid solution component (9) comprises a telescopic block (901), the telescopic block (901) is fixedly connected with the bottom of the inner wall of the heating pipe (5), a telescopic rod (902) is fixedly connected to the right side of the telescopic block (901), a coating block (903) is slidably connected to the surface of the telescopic rod (902), a telescopic film (904) is fixedly connected to the inner wall of the coating block (903), and an absorption ball (905) is fixedly connected to the inner wall of the telescopic film (904).

4. The method for processing the thermoplastically deformable Ti6242S high temperature titanium alloy wire according to claim 2, wherein the method comprises the following steps: the cooling assembly (8) further comprises a pushing ring (806), the pushing ring (806) is fixedly connected with the bottom of the inner wall of the flitch (804), the top of the pushing ring (806) is slidably connected with a cooling column (805), the top of the cooling column (805) is in contact with the top surface of the inner wall of the flitch (804), two sides of the cooling column (805) are fixedly connected with a spraying cavity (807), the inner wall of the flitch (804) is fixedly connected with a connecting frame (808), one end of the connecting frame (808) away from the flitch (804) is fixedly connected with a movable ring (809), the upper side and the lower side of the movable ring (809) are slidably connected with a cleaning column (810), one end of the movable ring (809) is fixedly connected with an adsorption cavity (811), the left side of the movable ring (809) is fixedly connected with a pressure ring (812), two sides of the upper side and the lower side of the pressure ring (812) are fixedly connected with telescopic pipes (813), an air pressure groove (815) is formed in the top of the adsorption cavity (811), the top of the adsorption cavity (811) is fixedly connected with a movable ring (809), one end of the movable ring (809) is fixedly connected with a compression film (817), and the bottom of the movable ring (817) is fixedly connected with a compression ball (817).

5. A method of processing a thermoplastically deformable Ti6242S high temperature titanium alloy wire as set forth in claim 3, wherein: the solid-melt assembly (9) further comprises a telescopic box (911), the top of the telescopic box (911) is in sliding connection with the bottom of the transmission rod (707), connecting arms (910) are fixedly connected to the two sides of the telescopic box (911), folding blocks (907) are fixedly connected to one ends, far away from the telescopic box (911), of the connecting arms (910), sliding pipes (906) are fixedly connected to the surfaces of the folding blocks (907), the sliding pipes (906) are in sliding connection with slot holes on the two sides of the transmission rod (707), fastening films (908) are fixedly connected to the top of the folding blocks (907), and adsorption discs (909) are fixedly connected to the inner walls of the folding blocks (907).

6. The method for processing the thermoplastically deformable Ti6242S high temperature titanium alloy wire according to claim 5, wherein the method comprises the following steps: the number of the connecting arms (910) is two, and the two connecting arms (910) are symmetrically arranged at two sides of the telescopic box (911) by taking the central line of the telescopic box (911) as a symmetrical axis.

7. A method of processing a thermoplastically deformable Ti6242S high temperature titanium alloy wire as set forth in claim 3, wherein: the number of the telescopic blocks (901) is two, and the two telescopic blocks (901) are symmetrically arranged at the bottom of the inner wall of the heating pipe (5) by taking the central line of the heating pipe (5) as a symmetrical axis.