FR2922796A1 - SINGLE-DUAL SHOULDER-SOLDERING DEVICE AND METHOD OF WELDING FRICTION-MIXED PIECES - Google Patents

Abstract

The invention relates to a device for welding parts (17, 18) by friction stirring with double shoulder, comprising a kneading pin (5), a lower shoulder (4) and an upper shoulder (3), the lower shoulder being mounted on the kneading pin so that it can be locked in the lower part (7) of said kneading pin, the upper shoulder being mounted on the knurling pin so that a position of the upper shoulder around the piece mixing device can be fixed by compression of elastic means (12) disposed between the main body and the upper shoulder, depending on a nipping force that is to be applied to the parts to be welded. The invention also relates to a friction stir welding method by means of the welding device according to the invention.

Description

The invention relates to a double-shoulder welding device for friction stir welding parts, also known as Friction Stir Welding Bobbin-Tool. The invention also relates to a welding method using such a device. The invention finds applications in any field requiring welding edge to edge or covering two parts that can be of metal alloys of all kinds, including aluminum alloy. Such a welding device is particularly suitable for welding aircraft fuselage panels, but also for welding thicker panels such as those used at the wing or the central wing box, as well as for welding any structural element of spacecraft, missile, motor vehicle etc. Such a device comprises a kneading pin for traversing the material to be welded and kneading as the progress of the welding device, and a lower shoulder and an upper shoulder. The lower shoulder is fixedly mounted or in translation on the kneading pin while the upper shoulder is mounted in translation along the kneading pin. It is thus possible to have a variable spacing between the two shoulders between which the parts to be welded are intended to be housed. The double-shoulder welding device makes it possible to create a heating on both sides of the welded joint and thus to have a better thermal distribution. In addition, the lower shoulder takes the pressure force exerted by the upper shoulder which allows to weld parts that are not able to resume the forging force of a conventional tool or retractable pin. Such a double-shoulder welding device requires complex equipment comprising a welding head with two actuators, each driving a shoulder. This tends to increase the bulk of the welding device as a whole and makes the robotization of the welding process using such a welding device more complex. In the invention, it is sought to provide a single-acting, double-shoulder welding device whose size is reduced. Another object of the invention is to provide such a welding device whose robotization is easy to implement. For this, in the invention, there is provided a double-shoulder welding device, for friction stir welding of parts, in which the clamping force generated between the shoulders does not require a large and complex actuator. The pinching force between the shoulders is generated by a spring, or any other elastic means, which is compressed by the upper shoulder before the welding device is started, and which in reaction pushes the upper shoulder against a face top of the parts to be welded during the entire duration of the actual welding step. The lower shoulder is fixed on the kneading pin of the welding device so as to rub against a lower face of the parts to be welded. The welding force is thus fixed even before controlling the welding device along the parts to be welded, by tightening the shoulders on the parts to be welded and compression of the spring. Advantageously, the flexibility of the spring used is a function of the intensity of the force to be applied to the parts to be welded. The invention therefore relates to a friction stir welding device with double shoulder, comprising a kneading pin fixedly mounted on a main body of a welding head of said device, a lower shoulder and an upper shoulder, the lower shoulder. being mounted on the kneading pin so that it can be locked at the bottom of said kneading pin, characterized in that the upper shoulder is mounted on the knurling pin so that a position of the upper shoulder around the mixing pin may be fixed by compression of elastic means disposed between the main body and the upper shoulder, depending on a nipping force that is desired to apply to the elements to be welded.

The lower and upper shoulders are mounted around the kneading pin so as to provide a space between the two shoulders in which are housed the parts to be welded. It is possible to modify the position of the lower shoulder at the bottom of the kneading pin, for example by screwing it onto the kneading pin, so as to lower or mount said lower shoulder on said pin. The lower shoulder can be locked in the chosen position by means of a nut.

The elastic means are for example one or more belleville washers, whose number and compliance may be variable depending on the parts to be welded, that is to say, their nature, their size and their end use.

In general, the greater the necessary pinching force, the more the elastic means are compressed by raising the lower shoulder along the kneading pin, which by reaction also raises the upper shoulder which compresses the elastic means. . The compression of the elastic means is upstream of the actual use of the welding device, so that the clamping force is fixed even before the start of the welding device. Advantageously, the upper shoulder is mounted fixed in rotation and free in translation on the main body. Thus, the rotation of the main body causes the rotation of the upper shoulder, which can however slide along the main body and the kneading pin, so as to compress more or less the elastic means depending on the compression ratio that the we wish to have. Otherwise, it is possible to mount the free upper shoulder in rotation and free in translation on the main body.

The position of the upper shoulder along the kneading pin, that is to say the amplitude of the translation, can be limited by a high stop and a low stop, allowing to fix a minimum compression and a maximum compression elastic means. The subject of the invention is also a process for welding parts by friction stirring by means of the double-shoulder welding device according to the invention, characterized in that it comprises the following additional steps: -on brings the parts to be welded, in the position that one wishes to obtain at the end of welding, between the shoulders of the welding device; - The lower shoulder is moved along the kneading pin so as to apply said shoulder against a lower face of the parts to be welded; the displacement of the lower pin in the direction of the parts to be welded, so as to compress the elastic means situated between the upper shoulder and the main body of the welding head, and thus to fix the desired pinching force between the two shoulders; the lower shoulder is locked in position on the kneading pin; the welding device is piloted along the parts to be welded. Tightening the nut, or any other means of fixing the lower shoulder, against said lower shoulder makes it possible to push the upper shoulder towards the main body, by compressing the elastic means. It is then the compression of the spring upstream even of the welding as such that sets the welding force applied to the parts to be welded. There is no need for a specific and bulky actuator to apply a force on each of the shoulders. According to examples of implementation of the method according to the invention, it is possible to provide all or part of the following additional steps: - A strong elastic means is used, so that the welding device applies a force on the parts solder which can decrease when the shoulders approach. This results in a welded joint thickness that varies very little, comparable to the welded joint that is obtained by using a welding device with double shoulder monoblock, that is to say with shoulders fixed on the kneading pin. - A low stiffness elastic means is used, so that the welding device applies a nearly constant force, even in the case where the thickness of the parts to be welded varies slightly from one end to the other of the welded joint that the we want to get. - Two plates are welded edge to edge, the kneading pin moving along two contiguous edges of the sheets to be welded. The welded joint obtained thus extends along said contiguous edges of the sheets. - Two sheets are welded by overlap, the kneading pin passing through a cumulative thickness of the two sheets to be welded. The invention will be better understood on reading the description which follows and on examining the figures which accompany it. These are presented as an indication and in no way limitative of the invention. The figures represent: FIG. 1: A schematic representation in partial cross-section of a welding head of a double-shoulder welding device according to a first embodiment of the invention, in which the upper shoulder is fixed in rotation; - Figure 2: A schematic representation in partial cross section of a double-shoulder welding device according to a second embodiment of the invention, wherein the upper shoulder is free to rotate, when used to weld two plates edge to edge. - Figure 3: A schematic representation in partial cross section of a double-shoulder welding device of Figure 1, when used to weld two edge-to-edge sheets. In Figure 1 is shown a welding head 1 of a double-shoulder welding device according to the invention. The welding head 1 comprises a main body 2 intended to be recessed on a head of the welding device (not shown), two shoulders 3, 4 and a kneading pin 5. More specifically, an upper shoulder 3 is mounted in translation in translation. upper part 6 of the kneading pin, while a lower shoulder 4 is mounted at the bottom 7 of said kneading pin 5. A high end 8 of said kneading pin 5 is screwed or embedded in the main body. The lower shoulder 4 can be screwed and unscrewed along the lower portion 7 of the kneading pin 5, depending on the use that is desired of the welding device, and the position of said lower shoulder 4 along the pin 5 is held by a nut 9. The upper shoulder 3 has a cylindrical tubular shape and has a U-shaped cross section. Thus, a low end 10 of the main body 2 is housed in the internal volume 11 of the upper shoulder 3 , said upper shoulder 3 being slidable along the lower end 10 of the main body 2. A key 14 makes it possible to link in rotation the main body 2 and the upper shoulder 3 so that the rotation of the main body causes the rotation of the upper shoulder 3. The sliding of the upper shoulder 3 along the lower end 10 of the main body 2 is limited by a low stop 15. Furthermore, belleville washers 12 are di sposées in the internal volume 11, between the lower end 10 of the main body 2 and a bearing wall 13 of the upper shoulder 3, intended to come into contact with the parts to be welded. The bearing surface 23 of the upper shoulder 3 and the bearing surface 21 of the lower shoulder 4 have a diameter close to that of the belleville washers 12. Of course, in another embodiment, it can be provided that the bearing surfaces 21, 23, or at least one, of the shoulders 3, 4 have a diameter completely different from the diameter of said washers 12. In FIG. 2 is shown a second embodiment of the welding head 1 according to FIG. invention, the upper shoulder 3 being here free in rotation and in translation relative to the main body 2. More specifically, the upper shoulder 3 is mounted in translation in the upper part 6 of the kneading pin 5 so as to slide along the end 10 of the main body 2, the sliding being limited by an upper stop 25 and a lower stop 26 flanking a stud 17.

Advantageously, a thrust bearing 16 is provided between the lower end 10 of the main body 2 and the spring washers 12, said thrust bearing 16 being attached to the lower end 10 of the main body. The thrust bearing 16 eliminates friction between the upper shoulder 3 and the main body 2 during the rotation of said main body 2.

As can be seen in FIG. 3, representing the welding head 2 of FIG. 1 during an edge-to-edge welding of two sheets 18, 19, said sheets 18, 19 are placed in a space 20 formed between the two shoulders. 3, 4, by joining one edge of the first sheet 18 against an edge of the second sheet 19.

The lower shoulder 4 is then raised up along the lower part 7 of the kneading pin 5 by screwing said lower shoulder 4 onto said peg 5, until the bearing surface 21 of the lower shoulder 4 comes to the contact of a lower face 22 of the plates 18, 19. The screwing is continued so as to raise the plates 18, 19 towards the bearing surface 23 of the upper shoulder 3, until a face upper 24 plates 18, 19 is in contact with said bearing surface 23. The lower shoulder 4 is still screwed in the direction of the upper shoulder 3, so as to slide back the upper shoulder 3 in the direction of the main body 2, and to compress the washers 12. Once the desired compression ratio of the washers 12 obtained, the lower shoulder 4 is held in position on the peg 5 by means of the nut 9, which maintains the crushing washers 12 and the position of the shoulder sup 3. The washers 12 will thus restore a clamping force on the upper shoulder 3 and by reaction on the lower shoulder 4 during the entire time of the driving of the welding device along the contiguous edges of the plates 18, 19. Thus for example, in the case of welding of aluminum alloy sheets with a thickness of 3.5 mm, using a double-shoulder welding device according to the invention composed of a pin with a diameter of 6 mm and two shoulders of diameter 12mm, it is possible to obtain the required effort of 2500 N by the series stacking of 6 packs of 5 washers in parallel of the following characteristics: 6.2mm inside diameter, 12mm outside diameter, - thickness 0.6mm, - total recoverable boom 0.35mm, and - maximum deliverable effort from 551 N to 75% of the total deflection. With such an assembly, a thickness variation of 0.1 mm gives a variation of the effort of 210 N or 8.4% of the total effort. The welding device according to the invention makes it possible to carry out friction stir welding, with an intensity welding force set in advance according to the needs. The welding head 1 can be secured to any welding device, without the need to provide specific actuators for controlling the shoulders 3, 4.

Claims (8)

1-device for welding parts (18, 19) friction double-shoulder mixing, comprising a kneading pin (5) fixedly mounted on a main body (2) of a welding head (1) of said device, a shoulder lower (4) and an upper shoulder (3), the lower shoulder being mounted on the kneading pin so that it can be locked in the lower part (7) of said kneading pin, characterized in that the upper shoulder is mounted on the mixing pin so that a position of the upper shoulder around the kneading pin can be fixed by compression of elastic means (12) disposed between the main body and the upper shoulder, depending on a pinch force that we want to apply to the parts to be welded. 2- friction stir welding device with double shoulder according to claim 1, characterized in that the upper shoulder is fixedly rotatably mounted (14) and free in translation (15) on the main body. 3- friction stir welding device with double shoulder according to claim 1, characterized in that the upper shoulder is rotatably mounted (17) and free in translation (25, 26) on the main body. 4- A method of welding parts (18, 19) friction stir by means of the double-shoulder welding device according to one of claims 1 to 2, characterized in that it comprises the following additional steps: - the parts are brought soldering, in the position that is desired at the end of welding, between the shoulders of the welding device; - moving the lower shoulder along the kneading pin so as to apply said shoulder against a lower face (22) of the parts to be welded; the displacement of the lower pin in the direction of the parts to be welded, so as to compress the elastic means situated between the upper shoulder and the main body of the welding head, and thus to fix the desired pinching force between the two shoulders; the lower shoulder is locked in position on the kneading pin, the welding device is piloted along the parts to be welded. 5-welding process according to claim 4, characterized in that it comprises the following step: - using a resilient means with stiffness, so that the welding device applies a force on the parts to be welded which can reduce when the shoulders approach. 6. Welding process according to claim 4, characterized in that it comprises the following step: - using a resilient means low stiffness, so that the welding device applies a nearly constant force on the parts to be welded. 7- welding process according to one of claims 4 to 6, characterized in that welding two plates edge to edge. 8- welding process according to one of claims 4 to 6, characterized in that welded two sheets per recovery.