FR3008271A1 - ANTI-ROTATION DEVICE FOR ARC PLASMA TORCH COMPONENTS - Google Patents

Abstract

The invention relates to an arc plasma torch assembly formed of a first component and a second component selected from a nozzle holder (1), an electrode holder (2) and an electrical insulating block (3). , an upstream nozzle (4), a downstream nozzle (5), an intermediate cap (6) and an upstream diffuser (7), the first and second components being symmetrical about a longitudinal axis (AA). According to the invention, the first component comprises at least one protuberance (9) and the second component comprises at least one orifice (10) in which at least a portion of said protuberance (9) is housed so as to prevent any rotation around it the longitudinal axis (AA) of the first component relative to the second component when screwing or unscrewing a holding member (11) in or around said first or second component.

Description

The invention relates to a set of components for an improved assembly arc plasma torch, and to an arc plasma torch comprising said assembly and an arc plasma cutting method using said torch. Usually, an arc plasma torch, in particular an arc plasma cutting torch, comprises a current-fed base and a torch head connected to said base, the base being attached to a cutting machine and serving interface between the torch head and the current generator, the high-voltage / high-frequency generator used to ignite the electric arc and the fluid feeds equipping an arc plasma cutting plant.

A torch head comprises the components necessary for the establishment of the electric arc used in an arc plasma cutting process, in particular an electrode, provided at its end with a thermo-emissive insert, and a upstream nozzle provided with an outlet channel. These components are supported respectively by an electrode holder and a nozzle holder. A torch head further comprises an electrical insulating block providing electrical insulation between the electrode holder and the nozzle holder. During the cutting phase, an electric arc is established between the electrode, more precisely at a thermo-emissive insert located at the lower end of the electrode, and the metal piece to be cut. The arc chamber, defined by the volume between the electrode and the upstream nozzle, is fed by a flow of plasma gas which is ionized in the electric arc. This supply is done by means of an upstream diffuser, generally provided with several injection ports for injecting the gas into the arc chamber. The flow of plasmagenic gas flows to the channel of the upstream nozzle in which the constriction of the arc takes place. It follows the ejection by the nozzle of an arc plasma jet whose high power density can provide the heat necessary for the melting of the material constituting the workpiece. The torch may also comprise a downstream nozzle arranged downstream of the upstream nozzle and for distributing a flow of protective fluid around the arc plasma jet. The shielding gas is distributed to the downstream nozzle by means of an intermediate cap carrying a downstream diffuser.

In a manner known per se, the downstream diffuser and / or the intermediate cap may comprise means for creating a fluid vortex, generally gas or water, which is ejected by the downstream nozzle and propagates up to the piece to be cut by swirling around the arc plasma produced by the torch. A holding part, or nut, is generally arranged at the downstream end of the torch head, preferably by screwing, so as to maintain the various components of the torch assembled to each other. However, a plasma cutting plant must be able to cut a wide range of materials and thicknesses. Typically, the range of sheet metal thicknesses to be cut is between 0.5 mm and 50 mm for mild steel parts and between 0.5 mm and 120 mm for stainless steel parts. Table 1 thus illustrates the change in intensity according to the thicknesses of cut material. Each process, that is to say a type of plasma gas, a pressure, a current intensity, corresponds to a set of consumables comprising an electrode, an upstream nozzle and / or a downstream nozzle of specific internal profiles, a diffuser upstream and / or downstream whose injection orifices have particular dimensions and shapes. Table 1 SOFT STEEL STAINLESS STEEL Intensity [A] Thickness [mm] Intensity [A] Thickness [mm] 30 0.5 - 3 20 0.5 - 3 50 0.8 - 6 40 and 60 1 - 6 80 4-10 90 4-12 130 8 -20 120 10 - 30 200 12 - 25 200 15 - 40 260 15 - 35 280 30 - 50 400 20 - 50 400 35 - 70 An operator implementing the plasma cutting method is therefore made to assemble and disassemble a large number times the torch components according to production needs. The ease of assembly and disassembly of consumables is therefore a crucial factor in terms of productivity and reducing the risk of errors in the assembly of torch components that can affect the operation of the process and the service life of the components. In addition, because of the frequency of replacement of consumables, it is important to control their manufacturing cost. For this, the consumables must be easy to machine. We therefore favor the use of axisymmetric geometry pieces, that is to say to symmetry of revolution or cylindrical, achievable by simple operations of turning and / or drilling, rather than by milling or other methods of more complex machining. This is particularly the case for the intermediate cap carrying the downstream diffuser, which is housed in a corresponding housing of the torch. This intermediate cap allows in particular the assembly of different components of the torch and can provide electrical insulation between the upstream nozzle and the downstream nozzle. In general, the intermediate cap is provided with a thread on which is screwed the retaining nut of the components of the torch. The phenomenon of rotation of the downstream diffuser in its housing induced by the screwing of the nut is then reduced only by sealing members such as O-rings arranged between the intermediate cap and the housing.

However, these solutions are not completely satisfactory. The friction force provided by these seals is not sufficient to completely prevent the rotation of the downstream diffuser in its housing during the unscrewing of the nut. This can make it difficult, if not impossible, to disassemble the nut. In addition, the rotation of the intermediate cap in its housing opposes the screwing of the nut and therefore to the correct positioning of the downstream nozzle.

These problems are accentuated by the deformations of the joints due to their aging, the dirt which is introduced into the threads and seize the assembly by threading. They also arise with other sets of torch components. An existing solution to remedy this is to use non-axisymmetric profile components. For example, the document WO2011000337 discloses a plasma torch in which the upstream nozzle is indexed relative to the nozzle holder by means of a particular machining of its external surface. However, this solution is not ideal because it leads to a significant increase in the manufacturing cost of the components due to their complex geometry, which affects the overall productivity of the plasma cutting plant.

In view of this, the problem to be solved is to overcome all or some of the disadvantages mentioned above, in particular by improving the assembly of components of an arc plasma torch to each other, without causing an excessive increase in manufacturing cost of said components. The solution of the invention is then a set for an arc plasma torch formed of a first component and a second component chosen from a nozzle holder, an electrode holder, an electrical insulating block, an upstream nozzle, a downstream nozzle, an intermediate cap and an upstream diffuser, the first and second components being symmetrical about a longitudinal axis, characterized in that the first component comprises at least one protuberance and the second component comprises at least one orifice wherein at least a portion of said protuberance is received so as to prevent any rotation about the longitudinal axis of the first component relative to the second component when screwing or unscrewing a holding member in or around said first or second components. Moreover, according to the embodiment considered, the assembly of the invention may comprise one or more of the following features: the orifice extends along said longitudinal axis from an upstream face of the second component and the protuberance extends along said longitudinal axis from a downstream face of the first component towards the orifice. the external profile of the protuberance is at least partially complementary to the internal profile of the orifice. the orifice comprises a cylindrical recess, preferably with a conical or frustoconical bottom. the first component comprises a plurality of protuberances. - The protuberances are distributed equidistantly at the downstream face. the first and second components are held together by means of a retaining piece screwed into or around the first or the second component. According to another aspect, the invention relates to a retaining piece shaped to maintain assembled the first and second components of an assembly according to one of the preceding claims by screwing in or around the first or the second component. Furthermore, the invention relates to an arc plasma torch comprising at least one assembly and a retaining piece according to the invention, as well as to a method of plasma arc cutting of a metal part. implementing such an arc plasma torch. The invention will now be better understood thanks to the following detailed description given with reference to the appended figures in which: FIG. 1 is a sectional view of an arc plasma torch according to the prior art; that is to say without implementation of the solution of the invention, - Figure 2 is a sectional view along another plane of the intermediate cap according to the prior art, - Figure 3 is a sectional view of An arc plasma torch comprising an assembly according to one embodiment of the invention; - Figure 4 is a partial sectional view of the assembly of Figure 3; - Figure 5 is a partial sectional view. a second component of an assembly according to the embodiment of the invention illustrated in Figure 3, and - Figure 6 is a top view of the second component of Figure 5. Figure 1 shows schematically the components of a arc plasma torch according to the prior art, namely the electrode 8, provided at its end lower part of a thermo-emissive insert 8a, the upstream nozzle 4, the plasma gas diffuser, also called the upstream diffuser 7, the nozzle holder 1 on which the upstream nozzle 4 is assembled, and the electrode holder 2 on which the electrode 8 is assembled. An insulating block 3 formed of an electrically insulating material is arranged between the electrode holder 2 and the nozzle holder 1. The electrode 8 and the upstream nozzle 4 defining between them the arc chamber 20 supplied with plasma gas by means of 7. Optionally, the torch head may comprise a downstream nozzle 5, an intermediate cap 6 and a downstream fluid diffuser 25 supplying liquid or gas to the downstream nozzle 5. These elements are positioned downstream of the diffuser upstream 7. The downstream nozzle 5 can perform various functions such as the cooling of the upstream nozzle 4 or the distribution of a secondary gas flow or a vortex of fluid, in particular water, around the column of arc established between the electrode and the piece to be cut. The downstream nozzle may thus comprise a plurality of grooves, machined preferably tangentially to the outlet orifice of the downstream nozzle. The vortex water is injected through the grooves and propagates by swirling to the outlet of the downstream nozzle. A holding member 11, or nut, is generally arranged and clamped to the downstream end of the torch head, preferably by screwing, so as to maintain the various components of the torch assembled to each other. Note that the upstream and downstream directions are defined in the direction given by the arrow on the longitudinal axis AA of the torch. As seen in Figure 1, the components of the torch are generally parts of revolution comprising an axial recess accommodated in each other. Their axes of symmetry are aligned along the longitudinal axis AA of the torch.

This is the case in particular of the intermediate cap 6 which engages in a corresponding housing in the torch. The intermediate cap 6 may comprise several grooves 12, machined preferably tangentially to the outlet orifice of the downstream nozzle. This intermediate cap 6 generally supports a downstream diffuser 25 generally having at its downstream end a plurality of orifices 24 for distributing vortex fluid. The fluid propagates by swirling to the outlet of the downstream nozzle. The intermediate cap 6 is provided on at least a portion of its outer surface with a thread 23 on which is screwed the nut 11. The friction of O-rings 21 arranged between the inner surface of the housing and the outer surface of the cap intermediate 6 opposes a rotation of the intermediate cap 6 in its housing, an O-ring 22 can also be arranged between an inner surface of the downstream diffuser 7 and an outer surface of the upstream nozzle 4.

Figure 2 shows a detailed view of an intermediate cap arrangement 6 and downstream diffuser 25. As explained above, the friction force provided by the seals is not sufficient to prevent the rotation of the intermediate cap in its housing during the screwing or the unscrewing of the holding part 11. It follows difficulties of disassembly of the nut and errors of positioning of the downstream nozzle during assembly of the nut. To remedy this, the present invention provides a set for an arc plasma torch formed of a first component and a second component with symmetry of revolution about a longitudinal axis AA. The first and second components may be the nozzle holder 1, the electrode holder 2, the electrical insulating block 3, the upstream nozzle 4, the downstream nozzle 5, the intermediate cap 6 and the upstream diffuser 7. Obviously, the first and second components may be second components are chosen distinct from each other. According to the invention, the first component comprises at least one protuberance 9 and the second component comprises at least one orifice 10 in which is housed at least a portion of said protuberance 9 so as to prevent any rotation about the longitudinal axis 25 AA of the first component relative to the second component when screwing or unscrewing a holding member 11 in or around said first or second components. Advantageously, it will be chosen to arrange said orifice 10 on a torch component of the consumable type, that is to say to be regularly replaced due to the wear that it undergoes during the plasma cutting process, such as the upstream nozzle 4, the downstream nozzle 5, the intermediate cap 6 and the upstream diffuser 7. Indeed the machining of an orifice 10 is significantly less expensive and fragile than that of a protuberance 9, which we prefer to arrange at a longer life torch component than a consumable, such as the nozzle holder 1, the electrode holder 2, the electrical insulating block 3. Figures 3 and 4 illustrate one embodiment of the invention. preferred embodiment of the invention wherein the first component is the nozzle holder 1 and the second component is the intermediate cap 6.

The intermediate cap 6 may comprise means for creating vortices as illustrated in FIG. 6. These means are adapted to and designed to create, during the operation of the torch, a jet of fluid, preferably water. , propagating to the cutting plate by swirling (vortices) around the arc plasma produced by the torch, which allows to constrict the plasma column, that is to say to form around it a fluid sleeve animated by a swirling motion. Preferably, the vortex generating means comprise several grooves, conduits or the like 12, preferably machined tangentially to the outlet orifice of the downstream nozzle 5. The vortex water is injected through the grooves 12 and propagates by swirling to the outlet orifice of the downstream nozzle 5.

In the context of the invention, the orifice 10 preferably extends along said longitudinal axis AA, that is to say along an axis parallel to the axis AA, from an upstream face 10a of the second component and the protuberance 9 extends along said longitudinal axis AA from a downstream face 9b of the first component towards the orifice 10. Advantageously, the external profile of the protuberance 9 is at least partially complementary to the internal profile of the orifice 10 In the context of the invention, the orifice 10 advantageously comprises a cylindrical recess, preferably with a conical or frustoconical bottom. The protuberances 9 are at least partly of cylindrical shape. Their diameter D must be large enough to withstand the shear forces acting on the protuberances during disassembly or mounting of the nut 11, while respecting the constraints in terms of sizing the components of the torch. On the other hand, the height H of the protuberances must not be too large so as not to weaken them. Advantageously, the protuberances have a diameter D between 1 and 8 mm and a height H between 2 and 10 mm.

Other geometries than cylindrical may however be used, such as parallelepiped, square or rectangular section, and elliptical or cruciform.

In order to improve the resistance to the shear forces exerted between the first and the second component when the holding part 11 is screwed or unscrewed, the first component advantageously comprises a plurality of protuberances 9, preferably between 1 and 12 More preferably, the protuberance 9 are 3 in number.

In the case of a plurality of protuberances 9, these may be distributed equidistantly at the downstream face 9b of the first component. As illustrated in FIG. 5, the corresponding orifices 10 are therefore separated by angles a, p and p. equal. This simple geometry makes it possible to reduce manufacturing costs. In the case where the implementation of the plasma cutting method requires an indexing of the first component relative to the second, it is possible to arrange the protuberances 9 and the corresponding holes 10 at separation angles of different values. The diameters of the protuberances or their geometry may also be different. This allows the assembly of the first and second components in a single position. As the case may be, the first component comprising the protuberance 9 may be formed of a single block or, as illustrated in FIGS. 3 and 4, be formed of at least two distinct elements, the protuberance 9 being arranged on one of the two elements. Preferably, the assembly of the invention comprises at least one sealing member 13, for example an O-ring, made of elastomeric material, arranged in a peripheral groove arranged in the outer and / or inner peripheral wall of the first and / or of the second component. Advantageously, the first and second components are formed of a metallic material, preferably selected from copper and its alloys, brass or silver and its alloys, except for the insulating block 3 which is formed mainly of an insulating material electric, preferably a plastic material.

At least one assembly according to the invention can equip any type of arc plasma torch, conventional or vortex fluid such as water. The main application of an arc plasma torch according to the invention is a method of cutting metal parts by arc plasma, with or without a water vortex. In addition to a more reliable and easier assembly of the first component relative to the second because of rotational locking, the assembly of the invention makes it possible to improve the accuracy of their relative positioning with respect to each other.

Claims (9)

REVENDICATIONS1. An arc plasma torch assembly formed of a first component and a second component selected from a nozzle carrier (1), an electrode holder (2), an electrical insulating block (3), an upstream nozzle ( 4), a downstream nozzle (5), an intermediate cap (6) and an upstream diffuser (7), the first and second components being symmetrical about a longitudinal axis (AA), characterized in that the first component comprises at least one protuberance (9) and the second component comprises at least one orifice (10) in which at least a portion of said protuberance (9) is housed so as to prevent any rotation about the longitudinal axis (AA ) of the first component relative to the second component when screwing or unscrewing a holding member (11) in or around said first or second component. 2. An assembly according to claim 1, characterized in that the orifice (10) extends along said longitudinal axis (AA) from an upstream face (10a) of the second component and the protrusion (9) extends along said longitudinal axis (AA) from a downstream face (9b) of the first component towards the orifice (10). 3. Assembly according to one of claims 1 or 2, characterized in that the outer profile of the protuberance (9) is at least partially complementary to the internal profile of the orifice (10). 4. Assembly according to one of the preceding claims, characterized in that the orifice (10) comprises a cylindrical recess, preferably with a conical or frustoconical bottom. 5. An assembly according to one of the preceding claims, characterized in that the first component comprises a plurality of protuberances (9). 30 6. The assembly of claim 5, characterized in that the protuberances (9) are distributed equidistantly at the downstream face (9b). 7. Assembly according to one of the preceding claims, characterized in that the first and second component are held together by means of a holding piece (11) screwed into or around the first or the second component. Arc plasma torch comprising at least one assembly according to one of claims 1 to 7. 9. A method of plasma arc cutting of a metal part using an arc plasma torch according to claim 8.