EP2448709A1

EP2448709A1 - Method for cladding a component with a self-supporting cladding closed by cold spraying

Info

Publication number: EP2448709A1
Application number: EP10723126A
Authority: EP
Inventors: Uwe Pyritz; Oliver Stier
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2009-06-30
Filing date: 2010-06-10
Publication date: 2012-05-09
Also published as: US20120097322A1; CN102470488A; DE102009031575A1; WO2011000674A1; CA2766848A1

Abstract

The invention relates to a method for producing a cladding (12, 13) on a component (11). According to the invention, the cladding (12, 13) is self-supporting and joined on the component (11) such that a joining gap (16) is created between the edges (15). Said joining gap (16) is closed by means of cold gas spraying with a bead-like layer (17) such that the cladding (16) can be used, for example, as corrosion protection. If the component (11) is made of aluminum, for example, the component (11) can be used as a current-conducting component (11) during galvanic coating. In this case, a cladding (12) made of titanium can be used as the corrosion protection layer.

Description

METHOD FOR LINING A COMPONENT TO A COLLAPSUALLY COVERED COLD SPRAYING

The invention relates to a method for dressing a component with a self-supporting panel.

Panels can be applied to components to improve their functionality. In this case, it is known, for example, that in the case of components it is possible to produce a covering made of flat products, which can be deformed in a suitable manner. These cladding can be used, for example, for current-carrying constructions for the galvanic coating of components. Such a component can for example consist of a holder for the components to be coated. In order to electrically contact them in the electrochemical coating bath, the component holder must be designed to be electrically conductive. For this purpose, preferably good conductors such as copper or aluminum are used

Commitment. To protect these metals from electrochemical dissolution, a titanium cladding is applied to the component which extends at least over the portion of the component which is immersed in the electrolyte.

It is basically known from US 2006/0113359 A1 that current-carrying components can be connected to one another by means of cold gas spraying. For this purpose, these electrical components, such as an electrical component and the metallic surface of a circuit board, aligned in the desired position to each other and by means of a material application by cold gas spraying electrically conductive each other connected. These connections can be made with an electrical resistance of less than 0.5 mΩ.

The object of the invention is to provide a method for cladding of components, which can be relatively comparatively inexpensive panels with relatively good protective effect produced.

This invention is achieved with a method for disguising a component according to the invention in that in the method, the component is first inserted into a self-supporting panel of a cladding material. The cladding is then assembled and / or deformed such that two edges of the cladding abut one another, align or overlap to form a joint gap. Under the meaning of the invention, all handling steps of the production are to be understood, which allow the formation of the joint gap. This can be done by handling preformed parts that have a corresponding fit, that results in the joining process, a butting edge or overlapping to form the joint gap. But it is also possible to plastically deform after the insertion of the component, the cladding material, whereby an inclusion of the component is formed and the edges of the cladding form a shock or overlap to form the joint gap. The cladding material may for this purpose consist of a flat semifinished product, for example a thin sheet. The joint gap may have a width of 0 to 5 mm, preferably 2 mm. As a result, manufacturing tolerances can be compensated advantageous.

Finally, the joint gap is closed, wherein the closure according to the invention is carried out by applying a gap bridging the joint gap by cold gas spraying. in this connection it is advantageous to a method by which comparatively thick layers can be generated in a short time. In addition, in the case of a suitable process control, the coating with the layer material can take place under atmospheric conditions, as a result of which cost-effective coating is possible. The main advantage of cold gas spraying, however, is that the cold gas jet containing the particulate layer material does not melt the cladding material, but because of its kinetic energy, the particles generate the layer and its adhesion to the cladding material due to plastic deformation. In this case, advantageously only the surface of the cladding material is attacked, whereby the good layer adhesion comes about. Melting of areas of the covering material which are remote from the surface can, however, be ruled out. In comparison, for example, for welding the joint gap can therefore be advantageously used with lower wall thicknesses of the cladding material, since a heat dissipation of welding energy in the cladding material is not necessary. As the decisive factor for the election wall thickness of the panel is therefore their real task to see. If the cladding is used, for example, as a corrosion protection for metallic components used in electrochemical coating, then for the selection of, for example, titanium or a titanium alloy for the cladding substantially thinner wall thicknesses for forming a reliable corrosion protection necessary than for a welding of the cladding held would have to be. Therefore, lining material can be saved as compared with welded panels in case of sealing by means of cold gas spraying. This is often more expensive in comparison to the material of the component to be clad due to the requirements on the cladding, which is why reduces wall thicknesses of the cladding advantageous to more economical components.

According to one embodiment of the invention, it is provided that the layer, which is applied by the cold gas spraying, is formed from a metal. Advantageously, most metals can be easily deposited by cold gas spraying, since their plastic deformation behavior is beneficial to the layer structure. In particular, a metal or a metal alloy can be selected which corresponds to the cladding, for example a titanium alloy or titanium. In this way, it is advantageously achieved that, for example, in the event of a corrosion stress, the electrochemical behavior of the layer is largely matched to the electrochemical behavior of the cladding material or even has identical corrosion behavior when identical materials are selected. As a result, the formation of local elements on the layer edge can be prevented, which is why even in the region of the joint gap a uniform corrosion of the cladding material comes about. The adjustment of the alloy of the

Layer material can be advantageously carried out by a suitable powder mixture of the particles used for the coating, wherein the alloy formation then during the

Layer structure takes place. Alternatively, it is of course also possible to use particles which consist of the relevant alloy.

For the use of the cladding as corrosion protection, it is particularly advantageous if the layer is applied with a thickness which is sufficient for the layer to be dense to ions. In particular, in electrochemical processes can thus be advantageously prevented that ions migrate through the layer and then through the joint gap and in this way a corrosion of the clad component could stand. It should be noted that due to their charge, the impermeability to ions meets higher requirements than the seal against uncharged chemical substances. If the layer is made of a metallic material, a tightness against ions can be achieved even at comparatively low layer thicknesses. The thickness of the cladding material can advantageously be at most 1 mm, preferably with a thickness of 100 to 300 μm, wherein a removal rate due to corrosive stress on the cladding over the intended service life of the clad component can also be taken into account.

It is particularly advantageous if the layer is produced at least above the joint gap in a thickness which is greater than or equal to the thickness of the cladding material. If the cladding material is designed with a suitable thickness in consideration of its function, a layer in the region of the joint gap which is greater than or equal to the thickness of the cladding material can advantageously be used to ensure that the requirements for the cladding material are also met in this area. Outside the joint gap, a smaller thickness of the layer can be provided. In particular, it is advantageous if the layer is produced in the form of a bead on the joint gap, wherein its greatest thickness is exactly above the joint gap, while on both sides of the lining towards the layer thickness decreases and so a transition between the

Layer and the surface of the panel creates.

Further details of the invention are described below with reference to the drawing. Identical or corresponding drawing elements are each provided with the same reference numerals and will only be explained several times as far as they give differences between the individual figures. Show it

1 shows the section through a component which has been produced according to an embodiment of the method according to the invention,

Figure 2 shows an embodiment of the method according to the invention, in which a cold gas spraying is used and

3 shows the top view of a component which after a

Embodiment of the method according to the invention was produced.

A component 11 according to FIG. 1 may be designed in the form of a rod, which is shown in section according to FIG. This component is provided with a cover 12 which has been bent from a sheet metal. The bending of the sheet is done in two steps. In a first step, the sheet is bent so far that it has a sufficiently wide gap for insertion of the component 11 (see dashed lines illustrated contour 13). After inserting the component 11, the sheet is closed, wherein an overlap region 14 is formed. Within this overlap region is formed between the edges 15 of the panel a joint gap 16, which must be sealed. This is done via a bead-shaped layer 17, which covers the joint gap 16 and the adjacent edge regions at the edges 13 of the cladding and thus leads to a hermetic ion-tight sealing of the cladding 12. The cladding 12 according to FIG. 2 has a double-shell construction, whereby the two joining gaps 16 can be seen below the bead-shaped layers 17 on the illustrated section of the component 11, which divide the cladding 12 into two half shells. The gap widths can be between 0 and 5 mm, preferably 2 mm, with a cladding thickness of 100 to 300 μm. The edges of the panel may be chamfered in a manner not shown, so that the gap width decreases towards the component. With a gap width greater than 0 mm, the bead advantageously also fixes the cladding on the component. It is also shown how the bead-shaped layer 17 is applied to the joint gap 16 by means of a cold gas jet 18 straight. This contains coating particles, which impinge on the surface of the cladding 12 at high speed and give the layer 17 by plastic deformation (not shown). It becomes clear that three-dimensional spatial curves of the joint gap 16 can also be coated by means of the cold gas jet 18 by means of suitable guidance. The component 11 is in fact bent so that the line of the joint gap 16 does not run in a straight line.

According to Figure 3, a holding device is shown as a component 11. This has a trunk 19, depart from the branches 20 with clamping devices 21 for components to be coated 22. The entire component 11 (ie trunk, branches and clamping device) is clad. On the branches 20, the bead-shaped layer 17 is indicated. The trunk is clad with two half-shells whose joining gaps are parallel to the plane of the drawing and therefore can not be seen in FIG. The component 11 can be used to immerse the components 22 to be coated in an electrolyte (not shown). At the end of the component 11, not shown, a device for receiving an electrical line is provided so that the component can be switched as an electrode and so an electrically conductive connection to the components to be coated 22 is formed. In order to ensure electrical conductivity, the component 11 is made of aluminum and the lining 12 is made of titanium. The layer 17 is made of titanium. The titanium cladding thus forms an effective corrosion protection for the aluminum component, even under the corrosive conditions that prevail in the galvanic coating of components.

Claims

claims

A method of dressing a component (11), wherein

The component (11) is inserted into a self-supporting cladding (12) made of a cladding material,

The paneling (12) is joined and / or deformed so that two edges of the panel abut, align or overlap one another to form a joint gap (16) and

• the joining gap (16) is closed, wherein the closing takes place by applying cold gas spraying by applying a layer (17) bridging the joint gap (16).

2. The method according to claim 1,

characterized,

in that the covering (12) is formed from a metal, in particular titanium or a titanium alloy.

3. The method according to claim 2,

characterized,

in that the layer (17) is formed from a metal, in particular from the metal or the metal alloy of the cladding.

4. Method according to one of the preceding claims, characterized in that

the layer (17) is applied with a thickness sufficient for the layer to be dense to ions.

5. The method according to any one of the preceding claims, characterized in that the layer is produced at least above the joining gap (16) in a thickness which is greater than or equal to the thickness of the cladding material.

6. The method according to one of the preceding claims, d a d u c h e c e n e c e n e,

that a cladding material having a thickness of at most 1 mm, preferably a thickness of 100 to 300 microns is used.

7. Method according to one of the preceding claims, characterized in that

the layer (17) is produced in the form of a bead following the joint gap (16).

8. Method according to one of the preceding claims, characterized in that

the lining (12) serves as corrosion protection for the component (11).

9. The method according to claim 8,

characterized,

in that a metallic component for electrochemical coating is clad as component (11).

10. The method according to claim 9,

characterized,

that the component (11) made of copper or aluminum or a

Alloy of these metals exists.