Method of manufacturing coiled tubing using multi-pass friction stir welding

Abstract

A method for manufacturing a long length of coiled metal tubing or the like using friction stir welding. Successive lengths of metal strip are friction stir welded using a three-pass welding technique to eliminate any edge defects in the resulting strip. The method includes one or more three-pass friction stir welding routines, each of which includes a first pass performed using a tool having a first rotational direction and a spiral bit pattern corresponding to the first rotational direction; a second pass using a tool having a second rotational direction and a spiral bit pattern corresponding to the second rotational direction; and a third pass using a tool having said second rotational direction and a spiral bit pattern corresponding to the second rotational direction.

Claims

1. A method of manufacturing coiled tubing, said method comprising: a. aligning end portions of two sheets of metallic parent stock so that a flush seam is established therebetween, said seam comprising a portion of each of the two sheets of parent stock; b. attaching a run-on tab to a first side edge surface of each of the two sheets of aligned parent stock, thereby forming a first tab interface; c. attaching a run-off tab to a second side edge surface of each of the two sheets of aligned parent stock, thereby forming a second tab interface; d. making a first friction stir welding pass, traversing said first tab interface, said seam, and said second tab interface, using a tool rotating in a first rotational direction and moving in a first longitudinal direction, thereby causing said seam to temporarily plastically deform, wherein a first edge defect is formed on an advancing side of the first friction stir welding pass within one of the sheets of metallic parent stock adjacent to the first tab interface, and wherein a second edge defect is formed on an opposite retreating side of the first friction stir welding pass within the other one of the sheets of metallic parent stock adjacent to the second tab interface; e. making a second friction stir welding pass offset from the advancing side of the first friction stir welding pass but within weld metal created during the first friction stir welding pass, traversing only said first tab interface using a tool rotating in a second, opposite rotational direction and moving in a second, opposite longitudinal direction, while said seam remains plastically deformed, thereby removing the first edge defect; f. making a third friction stir welding pass offset from the opposite retreating side of the first friction stir welding pass but within weld metal created during the first friction stir welding pass, traversing only said second tab interface using a tool rotating in said second, opposite rotational direction and moving in the first longitudinal direction, while said seam remains plastically deformed, thereby removing the second edge defect; and g. allowing said seam to cool in such a manner that the two portions of parent stock metal are thereafter seamlessly joined.

2. The method of manufacturing coiled tubing of claim 1, wherein the first rotational direction is a counterclockwise rotation.

3. The method of manufacturing coiled tubing of claim 1, wherein the second, opposite rotational direction is a clockwise rotation.

4. The method of manufacturing coiled tubing of claim 1, wherein the tool moves toward the run-off tab in first longitudinal direction, and wherein the tool moves toward the run-on tab in the second, opposite longitudinal direction.

5. The method of manufacturing coiled tubing of claim 1, further comprising repeating steps a.-g. using at least one of the other end portions of at least one of the two sheets of metallic parent stock.

6. The method of manufacturing coiled tubing of claim 1, wherein said run-on tab and said run off tab are removed after said seam has cooled, and wherein said first side edges and said second side edges are thereafter machine finished.

7. The method of manufacturing coiled tubing of claim 1, wherein the second friction stir welding pass is offset from the advancing side of the first friction stir welding pass by about 0.25 inches.

8. The method of manufacturing coiled tubing of claim 1, wherein the third friction stir welding pass is offset from the retreating side of the first friction stir welding pass by about 0.30 inches.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a schematic representation of metal flow into and away from the edge of the metal strip, as an FSW tool traverses through the tab and onto the edge of a metal strip while rotating in a counterclockwise manner.

(2) FIG. 2 is a schematic representation of a first pass as the FSW tool traverses through the joint region between two abutting strips; defects created across the run-on and run-off tabs are also depicted.

(3) FIG. 3 is an illustration of a second FSW pass, performed to repair the edge defect created at the run-on tab/structure interface during the first pass; the FSW tool is rotated in a clockwise manner in the second pass.

(4) FIG. 4 is an illustration of the third FSW pass, performed to repair an edge defect created at the run-off tab/structure interface during the first pass; the FSW tool is again rotated in a clockwise manner.

(5) FIG. 5 depicts a machining of the longitudinal edges of the FSW joint, so that no weldment exists beyond the lateral edges of the flat strip stock.

DETAILED DESCRIPTION

(6) The present invention overcomes the deficiencies in the prior art by providing an improved, nearly flawless weld joint that eliminates the need to clean or re-finish the resulting interior weld surface. The FSW methods described herein admit to production of a long, continuous loop of coiled tubing without creating excess weldment, and without compromising the molecular integrity of the parent feed stock.

(7) In contrast to the prior art, the lengths of strip stock do not require cutting or trimming at supplementary angles. Instead, the trailing end of one length and the leading end of the next successive length are simply butted until flush and then welded together using a friction stir welding technique that utilizes at least three successive passes, including two deformity repair passes, in order to repair and remove all edge defects created during the initial weld pass.

(8) As seen in FIG. 1, metal flows into and away from the edge of the metal strip when an FSW tool traverses through the tab and onto the edge of a metal strip. In this embodiment, the FSW is rotated in a counterclockwise manner, though those of ordinary skill in the pertinent arts will appreciate that the initial rotational direction is arbitrary with respect to the ultimate efficacy of the process, so long as the initial pass rotation direction and the direction of subsequent repair passes are reversed with respect to one another. For purposes of this application, therefore, the initial direction in which the FSW tool rotates is arbitrary, and not dependent upon any molecular curl issues or the like, and other tool rotation combinations are possible within the spirit and scope of the invention as described and claimed herein.

(9) In one specific though non-limiting embodiment, a full-penetration friction stir weld across a complete width of a sheet of 0.019 inch thick HSLA-90 steel utilizes run-on and run-off tabs, and a FSW tool traverses the metal sheet at a rate of around 300 rpm and 3 inches/minute, though again, these specific materials and dimensions are provided for illustrative purposes only, and are not limitative of the method claimed below.

(10) FIG. 2 shows how the first-pass friction stir weld 5 through joint 2 is made. Two sheets of metal strip stock 1A and 1B are butted together about a joint line 2. Small tabs of flat strip 3A and 3B are placed alongside each end of the joint line 2. A FSW tool 4 then traverses the joint line 2 while rotating counterclockwise, so that the two lengths 1A and 1B are joined together.

(11) In this example embodiment, frictional heat is generated as the FSW tool traverses joint line 2, thereby causing the opposing portions of metal to temporarily enter a plasticized, deformable condition. While the tool 4 traverses joint line 2, resulting plasticized material is spread along joint line 2, thereby creating a weld 5.

(12) In the depicted embodiment, FSW tool 4 begins its pass, moving across tab 3A, and traversing the joint line 2, and then completing the pass by traversing tab 3B. When FSW tool 4 traverses across tab/structure interface 11, an edge defect 6 is created on the resulting joined strip 13 on the advancing side of the FSW tool 4. Further, when the FSW tool 4 traverses across the tab/structure interface 12, an edge defect 7 is created on the resulting joined strip 13 on the retreating side.

(13) In a further embodiment, FIG. 3 shows how a second-pass remedial weld is completed in order to initiate removal of the defects created during the first pass. In the depicted embodiment, a second FSW tool with a reverse spiral on the tool shoulder 8 is used. In one specific though non-limiting embodiment, the weld path 9 is offset by approximately 0.25 inch to the advancing side of the first weld.

(14) In this embodiment, the second FSW tool 8 traverses through the sheet in a clockwise rotation. As the tool traverses the tab/structure interface 11, the tool advancing side draws metal across the tab/structure interface 11, towards the tab 3A, thus containing the edge defect 6 within the tab 3A. Correspondingly, on the tool 8 retreating side, no edge defect created, because the weld path 9 is within the weld metal created during the first weld pass 5.

(15) The example embodiment of FIG. 4 shows how a third-pass friction stir weld is completed. In one specific though non-limiting embodiment, the weld path 14 is offset by approximately 0.3 inch toward the retreating side of the first weld pass 5. The FSW tool 8 again traverses through the strip in a clockwise rotation.

(16) As the tool traverses the tab/structure interface 12, the tool advancing side draws metal into the tab 3B, thus containing the edge defect 7 within the tab 3B. Correspondingly, on the retreating side, the weld path 14 is within the weld metal created during the first weld pass 5; therefore, no defect is created in the resulting strip 13 (see FIG. 5).

(17) After the three weld passes (or more, if additional iterations of the process are desired) are completed, the tabs 3A and 3B are removed, as illustrated in FIG. 5. Machine grinders 10 or the like are then used to smooth the longitudinal edges of the strip stock. All defects are contained within the tabs 3A and 3B, and no defects are found in the resulting strip 13.

(18) In a further embodiment, the joined strip stock is subsequently rolled into a tube and seam welded, and in still further embodiments, the methods and means disclosed herein for seamlessly welding adjoining portions of metallic parent stock are applicable for a great many technical applications other than the manufacture of coiled tubing.

(19) The foregoing specification is provided for illustrative purposes only, and is not intended to describe all possible aspects of the present invention. Moreover, while the invention has been shown and described in detail with respect to several exemplary embodiments, those of ordinary skill in the art will appreciate that minor changes to the description, and various other modifications, omissions, and additions may also be made without departing from the spirit or scope thereof.