Hot-spinning Formation Method for Large-diameter Titanium Alloy Cylindrical Parts

Abstract

A hot-spinning formation method for large-diameter titanium alloy cylindrical parts. A workblank is placed in a resistance furnace to heated to 600-650° C., is maintained at this temperature for 0.5-1 h and is then taken out of the resistance furnace; after the workblank is heated, the inner diameter of the workblank becomes larger; the heated workblank is installed on a mandrel, and spinning is started when a maximum clearance between the workblank and the mandrel is less than 0.5 mm; the mandrel and the spinning rollers do not need to be preheated, and a multi-pass spinning process is adopted, such that the workblank can deform more uniformly. A vertical spinning lathe is used for spinning, the mandrel is easy to change, and the workblank is easy to assemble and disassemble.

Claims

1. A hot-spinning formation method for large-diameter titanium alloy cylindrical parts, wherein a to-be-machined workblank (3) is placed in a resistance furnace to be heated to 600-650° C., and is taken out of the resistance furnace after being maintained at this temperature for 0.5-1 h; the heated workblank (3) is disposed around a mandrel (2), and spinning is started when a maximum clearance between the workblank (3) and the mandrel (2) is less than 0.5 mm; after the spinning is ended, the workblank (3) is lifted by a pneumatic jack cylinder (5) to be removed from the mandrel, and when lifted to a designated position, the workblank (3) is completely removed from the mandrel, such that a titanium alloy cylindrical part is obtained; the hot-spinning formation method specifically comprises: Step 1: installing the mandrel (2) on a spinning lathe workbench (6); Step 2: starting the pneumatic jack cylinder (5), and enabling the pneumatic jack cylinder (5) to return to a working position; Step 3: placing the workblank (3) in the resistance furnace, heating the workblank (3) in the resistance furnace to 600-650° C., maintaining the workblank (3) at this temperature for 0.5-1 h, and then taking the workblank (3) out of the resistance furnace; Step 4: disposing the heated workblank (3), which is discharged out of the resistance furnace, around the mandrel (2), and clamping a lower end of the workblank (3) in a groove in the pneumatic jack cylinder (5); Step 5: when the heated workblank (3) shrinks to clamp the mandrel (2), starting spinning, and during the spinning process, enabling spinning rollers (4) to move downwards; Step 6: according to different passes of the spinning, repeating Step 5 in each pass of the spinning; and Step 7: when the spinning is ended, lifting, by the pneumatic jack cylinder (5), the workblank (3) to be removed from the mandrel, and when the workblank (3) is lifted to the designated position, completely removing the workblank (3) from the mandrel, such that the titanium alloy cylindrical part is obtained; a rotational speed of the mandrel (2) is 20-40 rad/min, a feed ratio is 2-4 mm/rad, and a reduction of each pass is 4-8 mm; an outer diameter of the workblank (3) is not less than 3 m.

2. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein the workblank (3) is in transitional fit with the mandrel (2), and a clearance between the workblank (3) and the mandrel (2) is less than or equal to 0.5 mm.

3. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein the number of the spinning rollers (4) is two, and the two spinning rollers (4) are distributed on the spinning lathe workbench (6) in a bilaterally symmetrical manner.

4. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein a surface of the mandrel (2) is coated with a layer of molybdenum disulfide oil, water-based graphite, or a glass lubricating protectant.

5. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein lifting rings (1) which are easy to assemble and disassemble are disposed at a top end of the mandrel (2).

6. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein the mandrel (2) is made of H13 hot work die steel, K403 high-temperature alloy, or 4Cr5MoSiV1.

7. The hot-spinning formation method for large-diameter titanium alloy cylindrical parts according to claim 1, wherein the spinning rollers (4) are made of H13 hot work die steel, W18Cr4V high-speed steel, or 4Cr5MoSiV1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] FIG. 1 is a structural diagram of a spin forming table provided by the invention;

[0029] FIG. 2 is a structural diagram of a large-diameter titanium alloy cylindrical part provided by the invention.

[0030] Reference signs: 1, lifting ring; 2, mandrel; 3, workblank; 4, spinning roller; 5, pneumatic jack cylinder; 6, spinning lathe workbench.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0031] Illustrative embodiments of the invention will be described in detail here, and the implementations described in the following illustrative embodiments are not all possible ones of the invention. They are merely examples of the method, which are consistent with some aspects of the invention detailed in the appended claims.

[0032] To allow those skilled in the art to gain a better understanding of the technical solutions of the invention, the invention will be described in further detail below in conjunction with the accompanying drawings and embodiments.

Embodiment 1

[0033] This embodiment provides a hot-spinning formation method for large-diameter titanium alloy cylindrical parts, which specifically comprises the following steps:

[0034] Step 1: a mandrel 2 is installed and fixed on a spinning lathe workbench 6 by lifting through lifting rings 1, and after the mandrel 2 is installed, an outer surface of the mandrel 2 is coated with a layer of molybdenum disulfide oil, wherein the mandrel 2 is made of H13 hot work die steel, and the diameter of the mandrel 2 is 2650 mm.

[0035] Step 2: a pneumatic jack cylinder 5 is started to return to a working position.

[0036] Step 3: a workblank 3 is placed in a resistance furnace to be heated to 650° C., is maintained at this temperature for 0.5 h, and is then discharged out of the resistance furnace.

[0037] Step 4: the heated workblank 3 discharged out of the resistance furnace is disposed around the mandrel 2 by lifting, and a lower end of the workblank 3 is clamped in a groove of the pneumatic jack cylinder 5, wherein the workblank 3 is made of TA1, and has an outer diameter of 2770 mm, a wall thickness of 60 mm and a height of 1000 mm.

[0038] Step 5: when the workblank 3 shrinks to a degree that a maximum clearance between the workblank 3 and the mandrel 2 is 0.5 mm, spinning is started, and during the spinning process, spinning rollers 4 move downwards, wherein the spinning rollers 4 are made of 4Cr5MoSiV1, and a rotational speed of the mandrel 2 is 20 rad/min.

[0039] Step 6: five-pass spinning is adopted, and Step 5 is repeated in each pass, wherein the reduction of the first pass is 8 mm, the feed rate of the first pass is 40 mm/min, and the feed ratio of the first pass is 2 mm/rad; the reduction of the second pass is 6.5 mm, the feed rate of the second pass is 50 mm/min, and the feed ratio of the second pass is 2.5 mm/rad; the reduction of the third pass is 6 mm, the feed rate of the third pass is 60 mm/min, and the feed ratio of the third pass is 3 mm/rad; the reduction of the fourth pass is 5.5 mm, the feed rate of the fourth pass is 70 mm/min, and the feed ratio of the fourth pass is 3.5 mm/rad; the reduction of the fifth pass is 4 mm, the feed rate of the fifth pass is 80 mm/min, and the feed ratio of the fifth pass is 4 mm/rad;

[0040] Step 7: after the spinning is ended, the workblank 3 is lifted by the pneumatic jack cylinder 5 to be removed from the mandrel; when lifted to an appropriate position, the workblank 3 is completely removed from the mandrel, wherein a cylindrical part formed by spinning has an outer diameter of 2710 mm and a wall thickness of 30 mm.

Embodiment 2

[0041] This embodiment provides another hot-spinning formation method for large-diameter titanium alloy cylindrical parts, which specifically comprises the following steps:

[0042] Step 1: a mandrel 2 is installed and fixed on a spinning lathe workbench 6 by lifting through lifting rings 1, and after the mandrel 2 is installed, an outer surface of the mandrel 2 is coated with a layer of molybdenum disulfide oil, wherein the mandrel 2 is made of H13 hot work die steel, and the diameter of the mandrel 2 is 2650 mm.

[0043] Step 2: a pneumatic jack cylinder 5 is started to return to a working position.

[0044] Step 3: a workblank 3 is placed in a resistance furnace to be heated to 600t, is maintained at this temperature for 1 h, and is then discharged out of the resistance furnace.

[0045] Step 4: the heated workblank 3 discharged out of the resistance furnace is disposed around the mandrel 2 by lifting, and a lower end of the workblank 3 is clamped in a groove of the pneumatic jack cylinder 5, wherein the workblank 3 is made of TA1, and has an outer diameter of 2770 mm, a wall thickness of 60 mm and a height of 1000 mm.

[0046] Step 5: when the workblank 3 shrinks to a degree that a maximum clearance between the workblank 3 and the mandrel 2 is 0.5 mm, spinning is started, and during the spinning process, spinning rollers 4 move downwards, wherein the spinning rollers 4 are made of 4Cr5MoSiV1, and a rotational speed of the mandrel 2 is 30 rad/min.

[0047] Step 6: five-pass spinning is adopted, and Step 5 is repeated in each pass, wherein the reduction of the first pass is 7.5 mm, the feed rate of the first pass is 45 mm/min, and the feed ratio of the first pass is 1.5 mm/rad; the reduction of the second pass is 7 mm, the feed rate of the second pass is 60 mm/min, and the feed ratio of the second pass is 2 mm/rad; the reduction of the third pass is 6 mm, the feed rate of the third pass is 69 mm/min, and the feed ratio of the third pass is 2.3 mm/rad; the reduction of the fourth pass is 5.5 mm, the feed rate of the fourth pass is 75 mm/min, and the feed ratio of the fourth pass is 2.5 mm/rad; the reduction of the fifth pass is 4 mm, the feed rate of the fifth pass is 90 mm/min, and the feed ratio of the fifth pass is 3 mm/rad;

[0048] Step 7: after the spinning is ended, the workblank 3 is lifted by the pneumatic jack cylinder 5 to be removed from the mandrel; when lifted to an appropriate position, the workblank 3 is completely removed from the mandrel, wherein a cylindrical part formed by spinning has an outer diameter of 2710 mm and a wall thickness of 30 mm.

Embodiment 3

[0049] This embodiment provides another hot-spinning formation method for large-diameter titanium alloy cylindrical parts, which specifically comprises the following steps:

[0050] Step 1: a mandrel 2 is installed and fixed on a spinning lathe workbench 6 by lifting through lifting rings 1, and after the mandrel 2 is installed, an outer surface of the mandrel 2 is coated with a layer of molybdenum disulfide oil, wherein the mandrel 2 is made of H13 hot work die steel, and the diameter of the mandrel 2 is 2950 mm.

[0051] Step 2: a pneumatic jack cylinder 5 is started to return to a working position.

[0052] Step 3: a workblank 3 is placed in a resistance furnace to be heated to 650° C., is maintained at this temperature for 0.5 h, and is then discharged out of the resistance furnace.

[0053] Step 4: the heated workblank 3 discharged out of the resistance furnace is disposed around the mandrel 2 by lifting, and a lower end of the workblank 3 is clamped in a groove of the pneumatic jack cylinder 5, wherein the workblank 3 is made of TA1, and has an outer diameter of 3010 mm, a wall thickness of 60 mm and a height of 1000 mm.

[0054] Step 5: when the workblank 3 contracts to a degree that a maximum clearance between the workblank 3 and the mandrel 2 is 0.5 mm, spinning is started, and during the spinning process, spinning rollers 4 move downwards, wherein the spinning rollers 4 are made of 4Cr5MoSiV1, and a rotational speed of the mandrel 2 is 20 rad/min.

[0055] Step 6: five-pass spinning is adopted, and Step 5 is repeated in each pass, wherein the reduction of the first pass is 7.5 mm, the feed rate of the first pass is 40 mm/min, and the feed ratio of the first pass is 2 mm/rad; the reduction of the second pass is 6.5 mm, the feed rate of the second pass is 50 mm/min, and the feed ratio of the second pass is 2.5 mm/rad; the reduction of the third pass is 6 mm, the feed rate of the third pass is 60 mm/min, and the feed ratio of the third pass is 3 mm/rad; the reduction of the fourth pass is 5.5 mm, the feed rate of the fourth pass is 70 mm/min, and the feed ratio of the fourth pass is 3.5 mm/rad; the reduction of the fifth pass is 4.5 mm, the feed rate of the fifth pass is 80 mm/min, and the feed ratio of the fifth pass is 4 mm/rad.

[0056] Step 7: after the spinning is ended, the workblank 3 is lifted by the pneumatic jack cylinder 5 to be removed from the mandrel; when lifted to an appropriate position, the workblank 3 is completely removed from the mandrel, wherein a cylindrical part formed by spinning has an outer diameter of 3000 mm and a wall thickness of 30 mm.

[0057] To sum up, the hot-spinning formation method provided by the invention can be used for spinning formation of titanium alloy cylindrical parts with an outer diameter over 3 m, the obtained cylindrical parts have good straightness and roundness, and the yield is high; and a vertical spinning lathe is used for spinning, the mandrel 2 is easy to change, the workblank 3 is easy to assemble and disassemble, and the use requirements of titanium cylinders on the surface of large-diameter high-end raw foil cathode rollers are met.

[0058] The above embodiments are merely specific embodiments of the invention, which are provided to help those skilled in the art understand or implement the invention. It is obvious to those skilled in the art to make various modifications of these embodiments. The general principle defined in this specification can be implemented in other embodiments without departing from the spirit or scope of the invention.

[0059] It should be understood that the invention is not limited to the above description, and various modifications and changes can be made to the invention without departing from the scope of the invention. The scope of the invention is limited merely by the appended claims.