Device and process for welding thermoplastic composite material parts

What is claimed is: 1. A thermoplastic welding device for assembling at least one first part made of thermoplastic composite material, a matrix of which is essentially formed by a thermoplastic resin, and at least one second part made of thermoplastic composite material of a type similar to the composite material of the first part, comprising: a magnetic induction head configured to induce current through a metal insert positioned in-between the at least one first part and the at least one second part in predetermined bonding zones corresponding to an interface between the at least one first part and the at least on second part where a thermoplastic weld seam is formed; a die configured for positioning the parts to be assembled including a nonmagnetic metallic support and a nonmagnetic insulating insert disposed within the support, where the nonmagnetic insulating insert defines the predetermined bonding zones in which thermoplastic weld seams are formed; a bladder defining, between said bladder and the die, an airtight volume and means for producing a partial vacuum in said airtight volume; means for displacement of the magnetic induction head close to the bonding zones and without contact with the bladder; wherein sacrificial parts are positioned at ends, following a direction for producing a weld seam, of the at least one first part in the cavity, formed for this purpose, made in the insulating insert, the device further comprising extensions located at ends of said metal insert on surfaces of said sacrificial parts; and, a nonstick film deposited between the extensions and each of the first parts and second parts with which said extensions are in contact in position in the tool. 2. The device as claimed in claim 1 , wherein the insulating insert comprises at least one cavity, a shape of which is suitable for holding at least one first part in position. 3. The device as claimed in claim 2 , wherein the insulating insert is made from a machinable nonmagnetic polymer material. 4. The device as claimed in claim 1 , wherein the insulating insert is immobilized in the support made from nonmagnetic metallic material. 5. The device as claimed in claim 1 , wherein shims are arranged on the insulating insert in the bonding zones in order to act as support for zones of the first parts that have to be bought to a melting point of the resin of the matrix of the composite material of said first part. 6. A process for the thermoplastic welding of at least one first part made of thermoplastic composite material with at least one second part (made of thermoplastic composite material by melting the resin of the matrices of said at least one first part and at least one second part by means of a magnetic induction head, comprising the successive steps of: positioning at least one first part in a cavity, having a shape suitable for holding said at least one first part, of an insulating insert disposed within a nonmagnetic metallic support of a die of a thermoplastic welding tool, the insulating insert corresponding to an interface between the at least one first part and the at least one second part where a thermoplastic weld seam is formed; placing metal inserts on the surf aces of the at least one first part corresponding to the bonding zones in which thermoplastic weld seams are formed; positioning at least one second part on the die in the relative position that said at least one second part should have with the at least one first part in the assembly to be produced; arranging a bladder so that said bladder and the die define an airtight volume wherein the at least one first part and the at least one second part are enclosed; creating a partial vacuum in the airtight volume in order to create, under the effect of the pressure of the air outside the airtight volume, a bearing force of the at least one second part on the at least one first part, at least in the bonding zones; contactless displacement of the magnetic induction head close to all the bonding zones so as to create in the metal inserts induced currents and a production of heat via the Joule effect so as to give rise to the local melting of the resin of the matrices of the composite material of the first and second parts, while maintaining the partial vacuum in the airtight volume; and, after cooling the welded parts to an ambient temperature, or at least to a temperature substantially below a softening point of the resin of the material of said parts, breaking the partial vacuum, disassembling the bladder and removing the assembly of parts welded together from the tool, wherein: sacrificial parts are positioned at ends, following a direction for producing a weld seam, of the at least one first part in the cavity, formed for the purpose, made in the insulating insert; the placing of metal inserts on the surfaces of the at least one first part is extended by extensions at ends of said metal insert on surfaces of said sacrificial parts; a nonstick film is deposited between the extensions and each of the first parts and second parts with which said extensions are in contact in position in the tool; the displacement of the magnetic induction head in order to produce the weld seam is extended at each of the ends of the weld seam on either side of a working length of said weld seam so as to begin and end the heating of the parts to be welded level with the sacrificial parts. 7. The process as claimed in claim 6 , comprising a step of placing shims between the insulating insert and the first parts in the bonding zones. 8. The process as claimed in claim 6 , comprising a step of placing a drainage fabric inserted between the parts positioned on the die and the bladder, to ensure a suction of air throughout the airtight volume between said die and said bladder. 9. The process as claimed in claim 6 , wherein the metal inserts are impregnated, before being positioned, with a thermoplastic resin that is compatible with the thermoplastic resin of the matrix of the composite material of the parts of the assembly to be produced.