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US-12623266-B2 - Three-roller device for high-accuracy wall reduction and uniformation

US12623266B2US 12623266 B2US12623266 B2US 12623266B2US-12623266-B2

Abstract

A device for high-accuracy wall reduction and uniformation includes: three rollers, three guide plates, and a plug. The three rollers are circumferentially evenly distributed along a rolling line which is a straight line of the moving direction of a billet being rolled. The three rollers are of unequal diameter rotating structure and each roller has a small end and a big end; three small ends of the three rollers are located at a first end of the device, and three big ends of the three rollers are located at a second end; and the three rollers are rotatable around their own axis. Each guide plate is disposed between every two adjacent rollers. The three guide plates rotatably abut against the three rollers, and are circumferentially evenly distributed along the rolling line. The plug is disposed in a forming space formed by the three rollers and three guide plates.

Inventors

  • Dong Liu
  • Jianguo Wang

Assignees

  • Hangon Precise Rolling Co., Ltd.

Dates

Publication Date
20260512
Application Date
20240218
Priority Date
20230220

Claims (15)

  1. 1 . A device, comprising: three rollers, the three rollers being circumferentially evenly distributed along a rolling line which is a straight line of a moving direction of a billet being rolled, wherein the three rollers are of unequal diameter rotating structure and each roller has a small end and a big end; three small ends of the three rollers are located at a first end of the device, and three big ends of the three rollers are located at a second end; and the three rollers are rotatable around their own axis; three guide plates, each guide plate being disposed between every two adjacent rollers, the three guide plates rotatably abutting against the three rollers, and being circumferentially evenly distributed along the rolling line; a plug, the plug being disposed in a forming space formed by the three rollers and three guide plates, wherein, the forming space is cylindrical, and an axis of the plug is coincident with the rolling line; the plug is an unequal diameter rotating structure having a small end and a big end; and the small end of the plug is located in an opening of the forming space, and the opening is a feed port of the billet; and the three rollers comprise two first rollers and one second roller; the two first rollers and the second roller are the same in shape; the two first rollers are the same in dimensions; a diameter of the two first rollers is less than that of the second roller in a plane parallel to the rolling line; and the small ends of the two first rollers and the small end of the second roller are located at the small end of the plug.
  2. 2 . The device of claim 1 , wherein the three rollers are the same in dimensions; and, the small end of the plug is disposed at the first end of the device, or the small end of the plug is disposed at the second end of the device.
  3. 3 . A method for wall reduction and uniformation using the device of claim 1 , the method comprising rotating the three rollers around their own axis in a revolving speed, feeding the billet from the small end to the big end of the plug into the forming space to contact the three rollers, driving the billet to move forward spirally along the rolling line to further contact the plug for wall reduction and uniformation, and outputting a final product from a gap formed by the three rollers, the three guide plates, and the plug.
  4. 4 . The method of claim 3 , further comprising heating the billet prior to being rolled.
  5. 5 . A device, comprising: three rollers, the three rollers being circumferentially evenly distributed along a rolling line which is a straight line of a moving direction of a billet being rolled, wherein the three rollers are of unequal diameter rotating structure and each roller has a small end and a big end; three small ends of the three rollers are located at a first end of the device, and three big ends of the three rollers are located at a second end; and the three rollers are rotatable around their own axis; three guide plates, each guide plate being disposed between every two adjacent rollers, the three guide plates rotatably abutting against the three rollers, and being circumferentially evenly distributed along the rolling line; a plug, the plug being disposed in a forming space formed by the three rollers and three guide plates, wherein, the forming space is cylindrical, and an axis of the plug is coincident with the rolling line; the plug is an unequal diameter rotating structure having a small end and a big end; and the small end of the plug is located in an opening of the forming space, and the opening is a feed port of the billet; and a unit pitch t of a rolled piece of the billet is: T = π · η 0 · D · tg ⁢ β ; wherein: β is a feed angle; D is a diameter of the billet; η 0 is an axial slip coefficient at an outlet of the device; along the rolling line, the plug comprises a preparation section, a wall reduction section, a uniform section, and a circular section; diameters of the preparation section, the wall reduction section, and the uniform section increase sequentially; an axial length of the preparation section is 0.4-0.6 t, an axial length of the uniform section is 2.0-2.5 t, and the axial length of the circular section is 0.9-1.1 t.
  6. 6 . The device of claim 5 , wherein a minimum diameter of the preparation section is 2R 1 , and a diameter at the connection between the preparation section and the wall reduction section is 2R 2 ; the wall reduction section comprises a first wall reduction section and a second wall reduction section; the preparation section is connected to the first wall reduction section, and a connection between the first wall reduction section and the second wall reduction section is 2R 3 ; the second wall reduction section is connected to the uniform section; a diameter at the connection between the uniform section and the circular section is 2R 4 ; a wall reduction amount of the first wall reduction section is ΔS1; a wall reduction amount of the second wall reduction section is ΔS2, and a total wall reduction amount of the wall reduction section is ΔS: Δ ⁢ S = Δ ⁢ S 1 + Δ ⁢ S 2 ; R 3 = D · ( 1 - I ) 2 - ( S - Δ ⁢ S 1 ) ; D is a diameter of the billet; S is a wall thickness of the billet; I is a reduction amount of the rolled piece; the reduction amount I of the rolled piece is 17% to 21%, and a front reduction amount W of the plug is 16% to 20%, and ΔS 1 /ΔS 2 is in the range of 0.5 to 2.
  7. 7 . The device of claim 6 , wherein outer walls of the wall reduction section and the circular section are curved surfaces.
  8. 8 . The device of claim 5 , wherein the three rollers are the same in dimensions; and, the small end of the plug is disposed at the first end of the device, or the small end of the plug is disposed at the second end of the device.
  9. 9 . A method for wall reduction and uniformation using the device of claim 5 , the method comprising rotating the three rollers around their own axis in a revolving speed, feeding the billet from the small end to the big end of the plug into the forming space to contact the three rollers, driving the billet to move forward spirally along the rolling line to further contact the plug for wall reduction and uniformation, and outputting a final product from a gap formed by the three rollers, the three guide plates, and the plug.
  10. 10 . The method of claim 9 , further comprising heating the billet prior to being rolled.
  11. 11 . A device, comprising: three rollers, the three rollers being circumferentially evenly distributed along a rolling line which is a straight line of a moving direction of a billet being rolled, wherein the three rollers are of unequal diameter rotating structure and each roller has a small end and a big end; three small ends of the three rollers are located at a first end of the device, and three big ends of the three rollers are located at a second end; and the three rollers are rotatable around their own axis; three guide plates, each guide plate being disposed between every two adjacent rollers, the three guide plates rotatably abutting against the three rollers, and being circumferentially evenly distributed along the rolling line; a plug, the plug being disposed in a forming space formed by the three rollers and three guide plates, wherein, the forming space is cylindrical, and an axis of the plug is coincident with the rolling line; the plug is an unequal diameter rotating structure having a small end and a big end; and the small end of the plug is located in an opening of the forming space, and the opening is a feed port of the billet; and each of the three rollers comprises a first roller body and a second roller body; a big end of the first roller body is connected to a small end of the second roller body to form a roller throat; a ratio of a diameter of the roller throat to a diameter of the billet is between 1 and 3; a ratio of an axial length of the three rollers to the diameter of the roller throat is between 1.5 and 3.5; a ratio of an axial length of the first roller body to an axial length of the second roller body is 3:5; a cone angle of the three rollers is 3.5° to 5°, and a rolling angle of the three rollers is 11° to 13°.
  12. 12 . The device of claim 11 , wherein a joint between the first roller body and the second roller body is chamfered, with a chamfer radius of not less than 500 mm.
  13. 13 . The device of claim 11 , wherein the three rollers are the same in dimensions; and, the small end of the plug is disposed at the first end of the device, or the small end of the plug is disposed at the second end of the device.
  14. 14 . A method for wall reduction and uniformation using the device of claim 11 , the method comprising rotating the three rollers around their own axis in a revolving speed, feeding the billet from the small end to the big end of the plug into the forming space to contact the three rollers, driving the billet to move forward spirally along the rolling line to further contact the plug for wall reduction and uniformation, and outputting a final product from a gap formed by the three rollers, the three guide plates, and the plug.
  15. 15 . The method of claim 14 , further comprising heating the billet prior to being rolled.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS Pursuant to 35 U.S.C.§ 119 and the Paris Convention Treaty, this application claims foreign priority to Chinese Patent Application No. 202310135721.2 filed Feb. 20, 2023, the contents of which, including any intervening amendments thereto, are incorporated herein by reference. Inquiries from the public to applicants or assignees concerning this document or the related applications should be directed to: Matthias Scholl P. C., Attn.: Dr. Matthias Scholl Esq., 245 First Street, 18th Floor, Cambridge, MA 02142. BACKGROUND The disclosure relates to a three-roller device for high-accuracy wall reduction and uniformation. Conventionally, hot rolled seamless steel pipe mill machine is used to manufacture seamless pipes, with the following technical processes: heating a tube blank, perforating, performing wall reduction and extension to obtain a raw tube, and sizing the raw tube. The following disadvantages are associated with the production process: 1) The methods involve many forming processes, multiple types of equipment, long production line, and complex equipment layout. During the production process, errors gradually accumulate in each step, making the final product unable to meet the specification requirements.2) The seamless steel pipe continuous rolling mill works in a continuous assembly line, which leads to equipment fatigue and wear. The accuracy of the wall thickness of seamless steel pipes is hardly improved, seriously affecting the production of seamless steel pipes with high accuracy requirement. SUMMARY To solve the aforesaid problems, the disclosure provides a three-roller device for high-accuracy wall reduction and uniformation comprising: three rollers, the three rollers being circumferentially evenly distributed along a rolling line which is a straight line of a moving direction of a billet being rolled, wherein the three rollers are of unequal diameter rotating structure and each roller has a small end and a big end; three small ends of the three rollers are located at a first end of the device, and three big ends of the three rollers are located at a second end; and the three rollers are rotatable around their own axis;three guide plates, each guide plate being disposed between every two adjacent rollers, the three guide plates rotatably abutting against the three rollers, and being circumferentially evenly distributed along the rolling line; anda plug, the plug being disposed in a forming space formed by the three rollers and three guide plates, wherein, the forming space is cylindrical, and an axis of the plug is coincident with the rolling line; the plug is an unequal diameter rotating structure having a small end and a big end; and the small end of the plug is located in an opening of the forming space, and the opening is a feed port of the billet. In a class of this embodiment, the three rollers are the same in dimensions; and, the small end of the plug is disposed at the first end of the device, or the small end of the plug is disposed at the second end of the device. In a class of this embodiment, the three rollers comprise two first rollers and one second roller; the two first rollers and the second roller are the same in shape; the two first rollers are the same in dimensions; a diameter of the two first rollers is less than that of the second roller in a plane parallel to the rolling line; and the small ends of the two first rollers and the small end of the second roller are located at the small end of the plug. In a class of this embodiment, a unit pitch t of a rolled piece of the billet is: T=π·η0·D·tg⁢β;β is a feed angle; D is a diameter of the billet; η0 is an axial slip coefficient at an outlet of the device;along the rolling line, the plug comprises a preparation section, a wall reduction section, a uniform section, and a circular section;diameters of the preparation section, the wall reduction section, and the uniform section increase sequentially; an axial length of the preparation section is 0.4-0.6 t, an axial length of the uniform section is 2.0-2.5 t, and the axial length of the circular section is 0.9-1.1 t. In a class of this embodiment, a minimum diameter of the preparation section is 2R1, and a diameter at the connection between the preparation section and the wall reduction section is 2R2; the wall reduction section comprises a first wall reduction section and a second wall reduction section; the preparation section is connected to the first wall reduction section, and the connection between the first wall reduction section and the second wall reduction section is 2R3; the second wall reduction section is connected to the uniform section; a diameter at the connection between the uniform section and the circular section is 2R4; a wall reduction amount of the first wall reduction section is ΔS1; a wall reduction amount of the second wall reduction section is ΔS2, and a total wall reduction amount of the wall reduction section is