The present invention is a method for attaching a tube to a workpiece.
In the prior art, a tube or pipe 10 of the prior art may be formed so that it includes a longitudinal opening 12 along its length (
In
Solid state welding, in which one of two heated metal tubes is rotated when the tubes are engaged to weld the tubes together end-to-end, is disclosed in U.S. Pat. No. 6,637,642. Among its benefits, solid state welding may achieve a weld without creating heat-affected zones in the tubes that are joined together using this technique. The ends of the tubes form a metallic bond, with a relatively uniform crystalline structure. However, solid state welding requires the application of substantial heat and force, and has not been utilized in repairing or otherwise modifying metal workpieces having a variety of configurations.
For the foregoing reasons, there is a need for a method and a system for attaching a tube to a workpiece that overcome or mitigate one or more of the deficiencies or disadvantages of the prior art.
In its broad aspect, the invention provides a method of attaching a metal tube having a tube wall defining a tube channel therein to a metal workpiece having a workpiece wall. The method includes forming a workpiece opening in the workpiece wall, the workpiece opening being at least partially defined by a workpiece opening wall surface in the workpiece wall. A tube engagement surface is formed on the tube wall. The tube engagement surface is formed for engagement with the workpiece opening wall surface.
Next, one or more heating elements are positioned in predetermined positions relative to the workpiece opening wall surface and the tube engagement surface. The heating elements are energized in a non-oxidizing atmosphere. With the energized heating element, in the non-oxidizing atmosphere, a workpiece heated portion is heated to a hot working temperature, at which the workpiece heated portion is at least partially plastically deformable. The workpiece heated portion extends into the workpiece wall from the workpiece opening wall surface.
With another energized heating element, in the non-oxidizing atmosphere, a tube heated portion is heated to the hot working temperature, at which the tube heated portion is at least partially plastically deformable. The tube heated portion extends into the tube wall from the tube engagement surface.
While the workpiece heated portion and the tube heated portion are at the hot working temperature, the tube is subjected to an engagement motion, to move the tube engagement surface relative to the workpiece opening wall surface. Also, while the tube is subjected to the engagement motion, and while the workpiece heated portion and the tube heated portion are at the hot working temperature, the tube is also subjected to a translocation motion, to push the tube engagement surface against the workpiece opening wall surface while the tube is subjected to the engagement motion.
While the tube is subjected to the engagement motion, and while the tube heated portion and the workpiece heated portion are at the hot working temperature, the tube engagement surface is pressed against the workpiece opening wall surface, to cause plastic deformation of the workpiece heated portion and of the tube heated portion as they engage each other, for creating a metallic bond between the tube and the workpiece. The tube and the workpiece are then allowed to cool, to bond the tube and the workpiece together.
The invention will be better understood with reference to the attached drawings, in which:
In the attached drawings, like reference numerals designate corresponding elements throughout. In particular, to simplify the description, the reference numerals used in
Reference is first made to
As will be described, the insert 120 preferably is formed to at least partially fit into the opening 112. It is preferred that the insert 120 has one or more insert engagement surfaces 122 (
Preferably, the opening wall surface 118 is heated in a first non-oxidizing atmosphere to a hot working temperature. As will also be described, when the opening wall surface 118 is heated to the hot working temperature, the opening wall surface 118 is plastically deformable. It is also preferred that the insert engagement surface 122 is heated in a second non-oxidizing atmosphere to the hot working temperature. When the insert engagement surface 122 is also heated to the hot working temperature, the insert engagement surface 122 is also plastically deformable.
The hot working temperature is below the metal's melting temperature. It will be understood that the “hot working temperature”, for the purposes hereof, may in fact be a range of temperatures. Those skilled in the art would be aware of suitable hot working temperatures for any particular metals, and suitable non-oxidizing atmospheres therefor.
Preferably, the insert 120 is subjected to an engagement motion, to move the insert engagement surface(s) 122 relative to the opening wall surface(s) 118. As will be described, the engagement motion may be as oscillating or vibrating motion. While the insert 120 is subjected to the engagement motion, and while the insert engagement surface 122 and the opening wall surface 118 are at the hot working temperature, the insert 120 preferably is also subjected to a translocation motion, to move the insert 120 at least partially into the opening 112, to engage the insert engagement surface(s) 122 with the opening wall surface(s) 118.
As will also be described, the insert 120 preferably is simultaneously subjected to both the engagement motion and the translocation motion, to engage the moving insert engagement surface(s) 122 with the opening wall surface(s) 118, to cause plastic deformation of the opening wall surface(s) 118 and of the insert engagement surface(s) 122 as they engage each other, for at least partially creating a metallic bond between the insert 120 and the workpiece 110. Finally, the insert 120 and the workpiece 110 are allowed to cool, to solidify the insert 120 and the workpiece 110 together.
Those skilled in the art would be aware that the opening wall surface(s) 118 and the insert engagement surface(s) 122 should be suitably prepared (e.g., cleaned) prior to their heating and subsequent engagement. Those skilled in the art would also be aware of suitable surface preparation techniques.
In the example illustrated in
Once the opening wall surface heating elements 124 have heated the opening wall surfaces 118 to the hot working temperature, they are removed, as indicated by arrows “A1”, “A2” (
The insert 120, while subjected to the engagement motion (as indicated by arrows “Y” in
The engagement of the insert engagement surface 122 with the opening wall surface 118, both of which are at the hot working temperature, results in a zone of material at the insert engagement and opening wall surfaces 122, 118 in which the insert 120 and the workpiece 110 are metallically bonded with each other. Such bonding is the result of the engagement force applied, and simultaneous engagement motion of the insert relative to the workpiece while the engaged surfaces 118, 122 are at the hot working temperature.
The method results in a workpiece and insert that are fused together to form a product in which heat-affected zones are absent. The process of the invention appears to result in a metallically bonded zone “Z” (
It will be understood that the metal of the workpiece and the metal of the insert may be any suitable materials that may be fused together by the method of the invention, e.g., alloys or metal elements, as the case may be. For instance, the metals that are fused together may include steel, aluminum, titanium, zirconium, Inconel™ and Hastelloy™. Due to the heat and shear/forging pressure that is applied, the material in the bonded zone has a uniform crystalline micro structure, which is relatively strong. For instance, it has been determined that, where the insert and the workpiece are made of steel, the steel in the bonded zone is bainitic.
The insert heating elements 126 and the opening surface heating elements 124 may be any suitable heating elements that can provide sufficient heat. Those skilled in the art would be aware of suitable heating elements. The heating elements 124, 126 preferably are configured for generally uniform heating of the opening wall surface(s) 118 and the insert engagement surface(s) 122 respectively. As can be seen, for example, in
It is preferred that the opening wall surface 118 is uniformly heated (or substantially uniformly heated) to the hot working temperature. To achieve this uniformity, it is also preferred that the opening wall 116 is uniformly heated to the hot working temperature to a first distance 128 from the opening wall surface 118 in the opening wall 116 (
Preferably, the insert engagement surface 122 is also uniformly heated (or substantially uniformly heated) to the hot working temperature. To achieve this uniformity, it is also preferred that the insert 120 is uniformly heated to the hot working temperature to a second distance 130 from the insert engagement surface 122 in the insert 120 (
As described above, the engagement motion of the insert 120 is intended to continue when, and after, the insert engagement surface 122 engages the opening wall engagement surface 118, to cause plastic deformation of each of the hot insert engagement surface 122 and the hot opening wall surface 118. It is believed that, due to the engagement motion and the force exerted to engage the insert with the workpiece, the materials of the insert engagement surface 122 and the opening wall surface 118 are commingled or mixed together, to a very small extent. To achieve this, the engagement motion continues for a short time after the surfaces 118, 122 engage each other. The engagement motion may be any suitable motion. For example, any repetitive motion of the insert 120 relative to the workpiece 110 may be suitable. For instance, in one embodiment, the engagement motion preferably is an oscillating motion relative to the workpiece 110.
As an example, as can be seen in
Alternatively, in another embodiment, the oscillating motion preferably is a linear motion of the insert, in which the insert is moved linearly relative to the workpiece, e.g., in any suitable direction. The oscillating motion may alternatively describe any suitable pattern, e.g., an arc or a partial ellipse.
In another alternative embodiment, the engagement motion preferably is a rotation of the insert 120 relative to the workpiece 110, e.g., about an axis “X” of the insert 120 (
As can be seen, e.g., in
In one embodiment, the opening wall surface 118 preferably is planar, and it is preferred that the insert engagement surface 122 also is planar (
As illustrated in
Those skilled in the art would appreciate that, in
As can be seen, e.g., in
As can also be seen, e.g., in
Once the insert 120 is positioned at least partially in the opening 112 and the insert has bonded with the workpiece, one or more portions 134 thereof may extend beyond the opening wall surface(s) 118 of the workpiece that the insert 120 has bonded with (
It will be understood that, during the engagement of the insert engagement surface 122 and the opening wall surface 118, a small portion of the material that is plastically deformed may be extruded from the insert and/or the workpiece, along an exposed part of the insert and/or the workpiece at the surfaces 118, 122. Depending on the specifications that the bonded or fused insert and the workpiece are required to meet, the extruded material, once cooled, may be required to be removed. In practice, however, such removal may be difficult, and time-consuming.
Those skilled in the art would appreciate that the insert 120 may have any suitable configuration. In one embodiment, illustrated in
As can also be seen in
The chamfered surfaces 140, 146 define spaces into which any plastically deformed material that is squeezed out as the insert is engaged with the workpiece may enter, so that such material is not extruded into the interior of the tube workpiece, or alternatively, not extruded onto the exterior surface of the tube workpiece.
In one embodiment, it is preferred that the insert 120 includes one or more notches 148 formed at the inner end 136, to minimize the amount of extruded material that may protrude into the interior of the tube workpiece.
The workpiece 110 may include two or more layers of respective metals. For example, as illustrated in
Where the workpiece 110 includes two or more layers of respective metals, it is preferred that the insert 120 also includes layers 184, 186 to fuse or bond with the layers 180, 182 respectively. When the insert 120 is at least partially located in the opening, the layers 184, 186 are metallically bondable with the layers 180, 182 respectively (
Heating elements 124′, 126′ preferably are used to heat the opening wall surface 118 and the insert engagement surface 122 respectively. The heating elements 124′ preferably include first and second parts 189, 190 for heating the first and second layers 180, 182 respectively. Also, the heating elements 126′ preferably include first and second parts 191, 192 for heating the layers 184, 186 of the insert 120 respectively.
In an alternative embodiment illustrated in
The engagement motion may be any suitable motion. For example, the engagement motion may be a regularly repeated motion (e.g., an oscillation) or an irregularly repeated motion.
It will be understood that heating elements and clamps are omitted from
In one embodiment, while the tube 250 is subjected to the engagement motion, and while the tube engagement surface 252 and the opening wall surface 218 are at the hot working temperature, the tube 250 preferably is also subjected to a translocation motion to move the tube 250 at least partially into the opening 212, for engaging the tube engagement surface 252 with the opening wall surface 218 while the tube is subjected to the engagement motion. As described above, this causes plastic deformation of the opening wall surface 218, and plastic deformation of the tube engagement surface 252 also as they engage each other, for at least partially creating a metallic bond between the tube 250 and the workpiece 210. Finally, the tube 250 and the workpiece 210 are allowed to cool, to solidify the tube 250 and the workpiece 210 together.
As can be seen in
The engagement motion may be, for example, a repeated or oscillating rotational motion of the tube 250 about its axis “2X”, as indicated by arrows “2Y1” and “2Y2” in
In
As described above, while the tube 250 is subjected to the engagement motion, it is preferably simultaneously moved in the direction indicated by arrow “2D”, to engage the tube engagement surface 252 with the opening wall surface 218. Preferably, after the tube engagement surface 252 initially engages the opening wall surface 218, the tube 250 is still moving in accordance with the engagement motion. At that point in the process, the tube 250 continues to be pressed against the workpiece 210 in the direction indicated by arrow “2D”, while the insert 250 is subject to the engagement motion. This results in the plastic deformation of the tube engagement surface 252 and the opening wall surface 218, resulting in the tube 250 fusing with the workpiece 210, as described above.
Those skilled in the art would appreciate that the tube 250 and the workpiece 210 rapidly cool after initial engagement, and the engagement motion ceases shortly after the initial engagement because the tube 250 and the workpiece 210 rapidly bond together, preventing further engagement motion.
In
The tube engagement surface 352 and the opening wall surface 318 are subjected to plastic deformation upon their engagement and shortly thereafter, to form a metallic bond between the tube 350 and the workpiece 310.
The workpiece 310 may be, for example, a body of a manifold, and the tube 350 may be one of several tubes (not shown) secured to the body, to form the manifold.
In another embodiment illustrated in
The tube engagement surface 252 preferably is formed on the tube wall 251 for engagement with the workpiece opening wall surface 218. Next, one or more heating elements 224 (
The heating elements 224 (
With the energized heating elements 224, in the non-oxidizing atmosphere, a workpiece heated portion 255 (
With the energized heating element 224, in the non-oxidizing atmosphere, a tube heated portion 257 (
It will be understood that the heating elements are omitted from
As can be seen in
Those skilled in the art would appreciate that, preferably, each of the heated portions 255, 257 is heated so that they are substantially uniformly heated to the hot working temperature. The heating elements 224 preferably are selected and configured to achieve uniform heating of the heated portions 255, 257. The heating elements 224 may be any heating elements that are suitable for the purpose. It is preferred that the heating elements 224 heat the heated portions 255, 257 by induction.
In one embodiment, while the workpiece heated portion 255 and the tube heated portion 257 are at the hot working temperature, the tube 250 preferably is subjected to an engagement motion, to move the tube engagement surface 252 relative to the workpiece opening wall surface 218. In addition, while the tube 250 is subjected to the engagement motion, and while the workpiece heated portion 255 and the tube heated portion 257 are at the hot working temperature, the tube 250 preferably is subjected to a translocation motion, to push the tube engagement surface 252 toward, and against, the workpiece opening wall surface 218 while the tube 250 is subjected to the engagement motion.
After the tube engagement surface 252 engages the workpiece opening wall surface 218, the engagement motion continues, until the tube and the workpiece are fused together.
As noted above, the engagement motion may be any suitable motion. As can be seen in
Next, while the tube 250 is subjected to the engagement motion, and while the tube heated portion 255 and the workpiece heated portion 257 are at the hot working temperature, the tube engagement surface 252 preferably is pressed against the workpiece opening wall surface 218, to cause plastic deformation of the workpiece heated portion 255 and of the tube heated portion 257 as they engage each other, for creating a metallic bond between the tube 250 and the workpiece 210. It is also preferred that the tube 250 and the workpiece 210 are then allowed to cool, to bond the tube 250 and the workpiece 210 together.
In
As noted above, the heated portions 255, 257 preferably are heated, by induction, to the hot working temperature, at which the metal in the heated portions is plastically deformable. Preferably, the heating elements 224 are controlled so that the temperature of the heated portions 255, 257 is kept below the melting temperature of the metal. The temperature is kept below the melting temperature so that heat-affected zones do not develop in the tube 250 or in the workpiece 210. Those skilled in the art would be aware of a melting temperature, and of a suitable hot working temperature, of the metal.
It will be understood that the pressure exerted to press the tube engagement surface 252 against the workpiece opening wall surface 218, while the heated portions are at the hot working temperature, and while the tube is subjected to the engagement motion, is relatively low. However, some pressure is needed, in order to subject the heated portions 255, 257 to shearing.
As noted above, the method of the invention results in a metallically bonded zone at which the tube 250 and the workpiece 210 are fused together, in the absence of any heat affected zones. Due to the engagement motion continuing while the tube engagement surface 252 is pressed against the workpiece opening wall surface 218, the material in the heated portions 255, 257 is subjected to a shearing action, in which the microstructure therein that is at or adjacent to the surfaces 252, 218 is sheared, resulting in a substantially uniform microstructure extending throughout the fused zone. The bonded or fused zone, in which the metal has a uniform crystalline microstructure, is believed to be generally the heated portions 255, 257, in which the metal was not melted. In
In practice, the heated portions 255, 257 and the fused zone “2Z” are relatively thin. The fused zone “2Z” as shown in
As noted above, the engagement motion may be any suitable motion. In one embodiment, for example, the engagement motion of the tube preferably is an oscillation about the axis “2X” of the tube.
Preferably, the tube engagement surface 252 and the workpiece opening wall surface 218 are formed to mate with each other (
Preferably, the workpiece 210 and the tube 250 are positioned to align their respective axes “2X”, 265.
In one embodiment, as can be seen in
In another alternative embodiment, illustrated in
As can be seen in
Preferably, heating elements 224′ are positioned proximal to the tube engagement surface 252′ and proximal to the workpiece opening wall surface 218′, for heating heated portions 255′, 257′ of the workpiece 210′ and the tube 250′.
As can be seen in
Preferably, while the heated portions 255′, 257′ are at the hot working temperature, and while the tube 250′ is subjected to the engagement motion, the tube 250′ is also subjected to the translocation motion, i.e., the tube 250′ preferably is moved toward the workpiece 210′, and after engagement, the tube engagement surface 252′ is pushed against the workpiece opening wall surface 218′. In addition, the tube 250′ continues to be subjected to the engagement motion while the tube engagement surface 252′ is pushed against the workpiece opening wall surface 218′, as indicated by arrow “3D” (
Accordingly, the engagement of the tube engagement surface 252′ with the workpiece opening wall surface 218′ while the tube 250′ is subjected to the engagement motion, while the heated portions 255′, 257′ are at the hot working temperature, causes shearing of the microstructure in the heated portions 255′, 257′, resulting in the heated portions 255′, 257′ becoming metallically bonded together. The heated portions 255′, 257′ cool relatively rapidly after engagement, and once the heated portions 255′, 257′ are bonded or fused together to form a fused zone “3Z” (
As can be seen in
In another alternative embodiment of the invention, the tube 250 preferably is subjected to the translocation motion, and the tube engagement surface 252 is pushed or pressed against the workpiece opening wall surface 218, while the heated portions 255, 257 are at the hot working temperature, but before the tube 250 is subjected to an engagement motion.
In this embodiment, while the workpiece heated portion 255 and the tube heated portion 257 are at the hot working temperature, and while the tube engagement surface 252 is pressed against the workpiece opening wall surface 218, the tube 250 preferably is subjected to an engagement motion in which the tube engagement surface 252 is moved relative to the workpiece opening wall surface 218, to cause plastic deformation of the workpiece heated portion 255 and of the tube heated portion 257, for creating a metallic bond between the tube 250 and the workpiece 210. The tube 250 and the workpiece 210 are then allowed to cool, to bond the tube 250 and the workpiece 210 together.
As noted above, the engagement motion may be any suitable motion, e.g., rotation or oscillation of the tube 250 about the tube axis “2X”.
In another alternative embodiment, the workpiece 210 preferably is subjected to the translocation motion, and the workpiece opening wall surface 218 preferably is pressed against the tube engagement surface 252 while the heated portions 255, 257 are at the hot working temperature, and before the tube 250 is subjected to the engagement motion.
Preferably, while the workpiece heated portion 255 and the tube heated portion 257 are at the hot working temperature, and while the workpiece opening wall surface 218 is pressed against the tube engagement surface 252, the tube 250 is subjected to an engagement motion in which the tube engagement surface 252 is moved relative to the workpiece opening wall surface 218, to cause plastic deformation of the workpiece heated portion 255 and of the tube heated portion 257, for creating a metallic bond between the tube 250 and the workpiece 210. The tube 250 and the workpiece 210 are then allowed to cool, to bond the tube 250 and the workpiece 210 together.
It will be understood that the engagement motion may be any suitable motion, e.g., rotation or oscillation of the tube 250 about the tube axis “2X”.
In yet another alternative embodiment of the method of the invention, it is preferred that the workpiece 210 is subjected to an engagement motion, while the heated portions 255, 257 are at the hot working temperature, and before the tube 250 is subjected to a translocation motion.
While the workpiece 210 is subjected to the engagement motion, and while the tube heated portion 257 and the workpiece heated portion 255 are at the hot working temperature, the tube engagement surface 252 preferably is pressed against the workpiece opening wall surface 218, to cause plastic deformation of the workpiece heated portion 255 and of the tube heated portion 257, for creating a metallic bond between the tube 250 and the workpiece 210. The tube 250 and the workpiece 210 are allowed to cool, to bond the tube 250 and the workpiece 210 together.
In one embodiment, a tube 1250 preferably includes one or more tube engagement surfaces 1252 that are positioned at respective predetermined angles relative to the tube axis “4X” of the tube 1250 (
It will be understood that the tube and the workpiece may be in any suitable form or configuration. For instance, in the example illustrated in
In the example illustrated in
Heating elements (not shown in
In one embodiment, while the heated portions 1255, 1257 are at the hot working temperature, the tube 1250 preferably is subjected to an engagement motion, to move the tube engagement surfaces 1252 relative to the workpiece opening wall surfaces 1218. As described above, the engagement motion may be any suitable motion. For example, the tube 1250 may be rotated or oscillated about the axis “4X”, as indicated by arrow “4H” in
While the tube 1250 is subjected to the engagement motion, and while the heated portions 1255, 1257 are at the hot working temperature, the tube 1250 is subjected to a translocation motion, moving the tube 1250 toward the workpiece 1210, i.e., in the direction indicated by arrow “4D” (
When the tube engagement surfaces 1252 engage the respective workpiece opening wall surfaces 1218, they are pressed against the workpiece opening wall surfaces 1218, while the tube engagement surfaces 1252 continue to be subjected to the engagement motion, and also while the heated portions 1255, 1257 are at the hot working temperature.
Also as described above, the heated portions 1255, 1257 are plastically deformed as a result. The heated portions 1255, 1257 lose heat once the heating elements are removed, and after the heated portions have been plastically deformed, sufficient heat has been lost that the tube 1250 and the workpiece 1210 are fused or bonded together. The engagement motion ceases once the tube 1250 and the workpiece 1210 are bonded or fused together.
In another alternative embodiment illustrated in
Preferably, the first insert 458 is provided having a first insert material that is metallically bondable with the metal of the workpiece 410. It is preferred that the first insert 458 is formed to at least partially fit into at least a part of the opening 412, as shown in
The defective region 511 may be defective, or damaged, or altered in any way so that the defective region should be replaced. For instance, the defective region may be a portion of the workpiece that has corroded or weakened over time, or that includes pitting or cracking resulting from use. The defective region may alternatively include defects formed when the workpiece was manufactured.
It will be understood that heating elements and clamps and other elements that may be needed for the method are omitted from
The first insert 458 preferably is subjected to a first engagement motion, to move the first insert engagement surface 452 relative to the opening wall surface 418. While the first insert 458 is subjected to the first engagement motion, and while the first insert engagement surface 452 and the opening wall surface 418 are both at the hot working temperature, the first insert 458 preferably is also subjected to a first translocation motion to move the first insert 458 at least partially into the opening 412, for engaging the first insert engagement surface 452 with the opening wall surface 418 while the first insert 458 is subjected to the engagement motion, to cause plastic deformation of the opening wall surface 418 and of the first insert engagement surface 452 as they engage each other, for at least partially creating a metallic bond between the first insert 458 and the remaining portion 456 of the workpiece 410.
In
Finally, the first insert 458 and the remaining portion 456 of the workpiece 410 preferably are permitted to cool, to provide a partially-repaired workpiece 460 (
As can be seen in
Those skilled in the art would appreciate that, when the first insert engagement surface 452 and the opening wall surface 418 are engaged with each other and plastically deformed, some material may be extruded from between the engaged surfaces 452, 418. For example, in
Preferably, in order to complete the repair of the damaged region 411 of the workpiece, the parts “J1”, “J2” of the opening 412 are to be filled, as will be described. In addition, however, in order to complete the repair of the damaged region 411, the extruded material “K1”, “K2” preferably is removed.
In order to achieve this, one or more supplementary openings 462 preferably are formed in the partially-repaired workpiece 460 (
It is also preferred that one or more second inserts 468 are provided that include a second insert material that is metallically bondable with the metal of the workpiece and the first insert (
Preferably, the supplementary opening wall surface 466 is heated in the non-oxidizing atmosphere to the hot working temperature, at which the supplementary opening wall surface 466 is plastically deformable. Similarly, it is preferred that the second insert engagement surface 470 is heated in the non-oxidizing atmosphere to the hot working temperature, at which the second insert engagement surface 470 is plastically deformable.
Preferably, the second insert 468 is subjected to a second engagement motion, to move the second insert engagement surface 470 relative to the supplementary opening wall surface 466. While the second insert 468 is subjected to the second engagement motion, and while the second insert engagement surface 470 and the supplementary opening wall surface 466 are at the hot working temperature, additionally the second insert 468 preferably is also subjected to a second translocation motion to move the second insert 468 at least partially into the supplementary opening intended for it, for engaging the second insert engagement surface 470 with the supplementary opening wall surface 466, to cause plastic deformation of the supplementary opening wall surface 466 and of the second insert engagement surface 470 as they engage each other, for at least partially creating a metallic bond between the second insert 468 and the partially-repaired workpiece 460.
In
It is also preferred that the second insert 468 and the partially-repaired workpiece 460 are allowed to cool, to form a repaired workpiece 472 (
In the example illustrated in
From the foregoing, it can be seen that the embodiment of the method of the invention illustrated in
It will be understood that the number, size and shape of the supplementary openings 462 may be any suitable number, size and shape. The first and second inserts 458, 468 may have any suitable configurations also.
For instance, in one embodiment, the supplementary opening 462 preferably is round in plan view. It is also preferred that the second insert 468 is a right circular cone. Preferably, the second insert 468 is frustoconical (
It will be understood that heating elements and clamps are omitted from
It will also be understood that the translocation motion of the first insert and the second inserts may, alternatively, be directed from the interior of the pipe or tube workpiece toward its exterior, if the relevant elements are formed to accommodate this.
Those skilled in the art would appreciate that such method (and other embodiments of the method of the invention described herein) may be utilized in situ, e.g., where the workpiece 410 cannot be moved, or at least cannot conveniently be moved.
In the embodiment of the method of the invention illustrated in
It will be understood that the embodiment of the method of the invention illustrated in
A partially-modified workpiece 560 is illustrated in
As illustrated in
It will be understood that the left and right first inserts 558, 559 are bonded with the body portion 556 using the embodiment of the method of the invention described above, e.g., such as the method used in connection with bonding the first insert 458 to the remaining portion 456 (
The heating elements and other elements needed for bonding the left and right first inserts 558, 559 with the body portion 556 are omitted from
It will be understood that some extruded material (not shown) may be extruded into the openings “L1”-“L3”.
It will also be understood that only two first inserts are illustrated in order to simplify the illustration. Those skilled in the art would appreciate that there may be any suitable number of first inserts, with a corresponding number of openings therebetween, depending on (among other things) the overall length of the opening that is to be filled.
In order to fill the openings “L1”-“L3”, and also to remove the extruded material therein, supplementary openings 561, 562, and 563 preferably are formed in the partially-modified workpiece 560 (
Preferably, second inserts 568 are provided that include second insert material that is bondable with the metal of the body portion 556, and with the metal of the left and right first inserts 558, 559. The second inserts 568 preferably are formed to fit into each of the supplementary openings 561, 562, 563. For clarity of illustration, in
Each of the supplementary openings 561, 562, 563 preferably is at least partially defined by a supplementary opening wall surface 566 (
Preferably, each of the supplementary opening wall surfaces 566 is heated in the non-oxidizing atmosphere to the hot working temperature, at which the supplementary opening wall surface 566 is plastically deformable. Similarly, it is preferred that the second insert engagement surface 570 of each second insert 568 is heated in the non-oxidizing atmosphere to the hot working temperature, at which the second insert engagement surface 570 is plastically deformable.
Preferably, the second insert 568 is subjected to a second engagement motion, to move the second insert engagement surface 570 relative to the supplementary opening wall surface 566 that the second insert 568 is positioned to engage. While the second insert 568 is subjected to the second engagement motion, and while the second insert engagement surface 570 and the supplementary opening wall surface 566 are at the hot working temperature, additionally the second insert 568 preferably is also subjected to a second translocation motion to move the second insert 568 at least partially into the supplementary opening intended for it, for engaging the second insert engagement surface 570 with the supplementary opening wall surface 566 thereof, to cause plastic deformation of the supplementary opening wall surface 566 and of the second insert engagement surface 570 as they engage each other, for at least partially creating a metallic bond between the second insert 568 and the partially-repaired workpiece 560.
In
It is also preferred that the second insert 568 and the partially-modified workpiece 560 are allowed to cool, to form a modified workpiece 572 (
In the example illustrated in
In one embodiment, each supplementary opening preferably is round in plan view. It is also preferred that the second insert 568 is a right circular cone. Preferably, the second insert 568 is frustoconical (
It will be understood that the number, size and shape of the supplementary openings may be any suitable number, size and shape. The first and second inserts 558, 559, 568 may have any suitable configurations also. The embodiment of the method as illustrated in
Those skilled in the art would appreciate that the embodiment of the method illustrated in
From the foregoing, it can be seen that the embodiment of the method of the invention illustrated in
It will be understood that heating elements and clamps are omitted from
It will also be understood that the translocation motion of the first inserts and the second inserts may, alternatively, be directed radially outwardly from the interior of the pipe or tube workpiece toward its exterior, where the relevant elements are formed to accommodate this.
Those skilled in the art would appreciate that such method (and other embodiments of the method of the invention described herein) may be utilized in situ, e.g., where the workpiece cannot be moved, or at least cannot conveniently be moved.
It will be appreciated by those skilled in the art that the invention can take many forms, and that such forms are within the scope of the invention as claimed. The scope of the claims should not be limited by the preferred embodiments set forth in the examples, but should be given the broadest interpretation consistent with the description as a whole.
This application is a continuation-in-part of U.S. patent application Ser. No. 16/821,104, filed on Mar. 17, 2020, the entirety of which is hereby incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 16821104 | Mar 2020 | US |
Child | 18175664 | US |