WO2008125282A1 - Component arrangement - Google Patents

Abstract

According to the invention, in a component arrangement, in which a plastic component and a metal component form a functional or structural assembly, the plastic component is equipped with a corrosion-inhibiting or corrosion-preventing agent (VCI) entering the gas phase. The arrangement of the two components allows for the agent to act on the metal component, particularly including the gas phase.

Description

318267 IP1 EN Robert Bosch GmbH £ p _o

318267 IP1 EN - Wiesmann ^ unich

J & April 2008 Component Arrangement

description

The invention relates to a component arrangement comprising a metallic component and a plastic component according to the preamble of patent claim 1.

Such component arrangements are e.g. frequently found in machines of industrial control and drive technology. The metallic component may e.g. a cast housing or a magnetizable steel and is as such typically at risk of corrosion. For transportation are common

Packaging films or papers are used, which are provided with a corrosion inhibitor - so-called VCI substances. The corrosion inhibitor exits the film and protects the metal component.

As an example of the aforementioned component arrangement, a bearing arrangement is mentioned, which is used in actuating magnets for valves or variable displacement pumps for supporting an armature in a pole tube. DE 103 27 875 A1 shows an electromagnet, in which a pole tube is inserted into a plain bearing bush, in which an armature is displaceable. DE 199 07 732 A1 discloses a similarly constructed electromagnet, wherein instead of the sliding bush a film storage is used. DE 197 16 517 A1 shows an electromagnet, in which between the armature and Polrohrinnenumfangswandung a sliding bush is provided as an abdominal bearing. An additional storage of the armature via a rod which passes through the armature in the axial direction and is guided in the pole tube. Both the rod and the sliding bush are made of a self-lubricating plastic.

The problem with all these solutions is that both the pole tube and the armature must be made of magnetizable material, so that the use of stainless steel usually fails. However, magnetizable steels are usually very susceptible to corrosion, so special measures must be taken to protect the electromagnet from corrosion. Such corrosion is not a problem with oil-filled solenoids during operation,

page 1 of 10

3ESTAYi ⁽ SIzUGSKOPIE 318267 IP1 EN

because the corrosion of the hydraulic oil is prevented. In the period leading up to operation or during dry operation of the electromagnet, corrosion is currently prevented by introducing a corrosion-inhibiting medium into the magnet interior during assembly of the magnet. Such a filling with a corrosion-inhibiting fluid can lead to "sticking" of the components or to the binding of dirt inside the magnet under unfavorable operating conditions. When using corrosion-inhibiting gases there is a risk that they will volatilize during storage, so that the corrosion protection is guaranteed only for a relatively short time.

This problem occurs in virtually all applications in which a

Component is used made of a corrosion-sensitive material, especially when it is performed in a plain bearing or other guide.

The invention has for its object to provide a component assembly in which the corrosion protection is improved.

According to the invention, in a component arrangement in which a plastic component and a metallic component form a functional or structural unit, the plastic component is provided with a corrosion-inhibiting or corrosion-inhibiting substance which transgresses the gas phase. The arrangement of the two components allows the action of the substance on the metallic component, in particular involving the gas phase.

In this way, a functional component or a structural plastic component with an additional function, namely the corrosion protection provided by a nearby arranged metallic component. A transport packaging equipped with anti-corrosion properties can be reduced or eliminated or replaced by standard packaging, cardboard boxes, etc. This reduces the logistics costs for the transport of building units. If the installation space is sufficiently tight, corrosion protection over the service life of a unit may possibly be achieved. Plastic parts are almost ubiquitous in today's mechanical engineering, electronics and factory automation products. Therefore, with little effort, an integrated corrosion protection can be achieved, at least for transport purposes.

Page 2 of 10 318267 IP1 DE Further advantageous embodiments of the invention are the subject of

Dependent claims.

The anti-corrosive or corrosion-preventing substance can be particularly effective when it is discharged into an enclosed interior. The interior can be defined primarily by the metallic component. The metallic component can also be arranged in the interior. The plastic component is preferably arranged in the interior or it forms a boundary surface of the interior.

In principle, many different plastics are suitable as carriers for a corrosion-inhibiting or corrosion-inhibiting substance, in particular thermoplastics, thermosets, elastomers, fiber-reinforced plastics or plastics provided with fillers. Possibly. For example, the plastic in question may have a certain porosity in order to absorb the corrosion-inhibiting or corrosion-inhibiting substance. In particular, polyamides, polytetrafluoroethylene or polyethylene and polycarbonates can be provided with corrosion-inhibiting or corrosion-inhibiting substances.

The plastic component can in principle fulfill all the functions and structural requirements for which conventional plastic components are used. Examples are elastic damping elements, bearing elements in plain bearings, sliding blocks, bearing segments, cages in roller, ball or needle bearings, transmission links for mechanical movements such as valve tappets, shafts, etc., spacers such as discs, especially anti-adhesive discs in magnets, supports for electronic boards, stop elements for Limiting a movement in

Linear drives, housing components, bushings, sealing elements such as O-rings, R-rings or sealing sleeves, if applicable, sliding bands, or valve cones or seats in pneumatic or hydraulic valves, or pistons in piston-cylinder units.

Preferably, a sliding or bearing element of a bearing is designed as a carrier for corrosion-inhibiting or preventing substance (corrosion inhibitor), which passes into the gas phase and settles on the corrosion-sensitive material or forms an atmosphere surrounding the corrosion-sensitive material, so that it reliably protected against corrosion is. This corrosion protection is guaranteed even with prolonged storage or prolonged operation of the respective bearing pairing. This transition of inhibitors into the gas phase and the settling of the substances on the corrosion-sensitive material is

Page 3 of 10 318267 IP1 EN is largely independent of the usual temperatures or humidities, so that the corrosion protection is effective even in extreme climatic conditions.

Particularly suitable so-called VCI substances (Volatile Corrosion Inhibitor) have been found. These often consist of salts, such as nitrides, amines, which form a closed protective layer on the surface to be protected and penetrate existing water films or the like. The presence of these VCI substances inhibits the anodic and cathodic partial reactions in the course of corrosion, it being possible, depending on the configuration of the carrier layer, to achieve a duration of action of up to several years.

Although the use of VCI substances is already known per se from packaging technology, these are incorporated in packaging films in which the component to be protected is packaged. Within this packaging, the transition of the inhibitors into the gas phase then creates a saturated, corrosion-resistant atmosphere. When opening this packaging of the workpiece, however, volatilize the VCI, so that then no longer any corrosion protection. That With such a conventional technique, the above-described electromagnets could indeed pack, so that the corrosion protection during storage time remains - in a dry operation of the electromagnets or when decommissioning an oil-filled electromagnet, in which the oil passes out of the interior, would be However, no corrosion protection more available, so that even then the problem described above results.

According to the invention it is particularly preferred if the carrier for the one

Corrosion-inhibiting substances made of plastic, so that the corrosion-sensitive component slides along this plastic carrier.

The carrier is particularly easy to handle when it is designed as a film.

An important application of the invention is in electromagnets, wherein the above-described carrier can be formed for example between an armature and a pole tube (prone storage and rod storage). In this case, the carrier can be designed as a film or as a plastic bush in which the armature is guided axially displaceable.

Page 4 of 10 The invention can be used generally with bearing elements in which the bearing surface can be designed as a support for such corrosion-inhibiting substances. For example, bearing bushes made of plastic (PTFE, for example) or composite or plastic guide rings for components, such as piston rods or pistons of Hydrozylindem for equipment according to the invention are equipped with ausgasenden corrosion inhibitors. In the case of bearing elements, wear can advantageously be used to gradually open further depots of corrosion-inhibiting substances embedded in the bearing element as part of the removal of material.

The invention is, as stated, not limited to bearing elements, but may include any component arrangements of a plastic component and a metallic potentially corrosion-prone component, wherein it is ensured that the corrosion-inhibiting or substance which is released from the plastic component in gaseous form, on the metallic Can act component.

An embodiment of the invention will be explained in more detail below with reference to a single schematic drawing showing a greatly simplified cross-section of an electromagnet.

The basic structure of an electromagnet 1 is known, for example, from DE 199 52 800 A1, so that in the following only the essential components for understanding the invention will be described. Such an electromagnet 1 has a coil accommodating a coil housing 2, which surrounds a pole tube 4 in sections. On the coil housing 2, a plug socket 3 for the electrical connection of the electromagnet 1 is placed. The pole tube 4 has an anchor receiving space 6, in which an armature 8 is guided axially displaceable also from magnetizable material. This armature 8 has a plunger 10 which extends through a plunger channel 11 set radially back relative to the armature receiving space 6 and protrudes from the left end portion of the pole tube 4 in the figure. This plunger 10 acts, for example, on a valve spool of a valve in order to adjust this when the electromagnet 1 is energized. The left in the figure, protruding from the bobbin case 2 end portion of the pole tube is formed as a fastening shoulder 12, via which the solenoid 1 can be screwed to the valve to be actuated. The other end portion of the pole tube 4 is closed by an end piece 14, which is connected to the peripheral wall of the pole tube

Page 5 of 10 318267 IP1 EN 4 is connected by crimping. This end piece 14 is provided with an external thread on which a fastening nut 16 is screwed, which biases the coil housing 2 against a radial shoulder 18 in order to fix it in the radial direction. The recorded in the anchor receiving space 6 anchor 8 is provided with axially parallel extending holes 20 through which the limited by the respective end faces of the armature receiving space 6 are interconnected so that when oil-filled operation of the electromagnet 1, the oil from the shrinking frontal space in the other , overflowing space can flow.

According to the invention, the inner circumferential wall of the anchor receiving space is coated or lined with a bearing foil 22 along which the outer circumference of the armature 8 is guided. This bearing foil fulfills a double function: on the one hand, it reduces the sliding friction between the armature 8 and the pole tube 4, so that the electromagnet 1 can be adjusted very easily and with little delay. On the other hand, the bearing foil 22 serves as a carrier for the VCI substances described at the outset, which outgas during storage and during a dry operation, so that an atmosphere of corrosion-preventing substances forms in the interior of the electromagnet 1 Settle peripheral surfaces of the components and thus form a moisture-displacing and moisture-impermeable layer, so that corrosion is effectively prevented. It is advantageous that the electromagnetic interior is relatively small and little air exchange takes place, so that this atmosphere is very long. Even with low Lekagen the anticorrosive effect is not deteriorated, since then further substances from the bearing film 2 diffuse out until a thermodynamic and chemical equilibrium state between the gas phase and embedded in the bearing film phase.

In the above-described embodiment, a bearing foil 22 is used. Instead of such a film, of course, a bearing bush made of plastic or of a composite material (so-called DV sockets) could be used. In principle, the support for the VCI substances could also be provided on the outer circumference of the armature 8, i. be arranged of the movable member.

According to the invention, in a component arrangement in which a plastic component and a metallic component form a functional or structural structural unit, the plastic component is provided with a corrosion-inhibiting or corrosion-inhibiting substance which transgresses the gas phase. The

Page 6 of 10 318267 IP1 EN Arrangement of the two components allows the action of the substance on the metallic component, in particular involving the gas phase.

In this way, a functional component or a structural plastic component with an additional function, namely the corrosion protection provided by a nearby arranged metallic component. One with

Corrosion protection properties equipped transport packaging can be reduced or eliminated or replaced by a standard packaging, cardboard boxes, etc. This reduces the logistics costs for the transport of construction units. If the installation space is sufficiently tight, corrosion protection over the service life of a unit may possibly be achieved. Plastic parts are almost ubiquitous in today's mechanical engineering, electronics and factory automation products. Therefore, with little effort, an integrated corrosion protection can be achieved, at least for transport purposes.

Page 7 of 10

Claims

318267 IP1 DEPatentansprüche 1. Component arrangement of a metallic component and a plastic component for forming a functional or structural unit, characterized in that the plastic component is designed as a carrier (22) for a corrosion-inhibiting or preventing substance that passes into the gas phase, and that the spatial arrangement of the plastic component and the metallic component allows an action of the substance on the metallic component. 2. Component arrangement according to claim 1, characterized in that a substantially enclosed interior space is formed, and that the Plastic component is arranged so that the substance is discharged into the interior. 3. Component arrangement according to claim 1 or 2, characterized in that the plastic component has at least one of the following functions, namely Damping element, sliding bearing element, cage element, transmitter of linear or rotary movements, spacers, stop, housing element, sealing element, piston in a piston-cylinder arrangement. 4. Component arrangement according to one of the preceding claims, characterized in that the plastic component comprises at least thermoplastics, thermosets, elastomers, or fiber-reinforced plastics or plastics provided with fillers. 5. Component arrangement according to one of the preceding claims, characterized in that the substance comprises so-called VCI substances, in particular water vapor-containing substances such as salts (nitrides, amines). 6. Component arrangement according to one of claims 1 to 5, designed as a bearing arrangement for a movable along a sliding or bearing element Component consisting of a corrosion-sensitive material or with a component consisting of a corrosion-sensitive material Page 9 of 10 318267 IP1 DE sammenwirkt, characterized in that the sliding or bearing element (22) is formed as a carrier for the anti-corrosive or preventive substance which undergoes gas phase and which protects the corrosion-sensitive material from corrosion by forming a layer deposited thereon or an atmosphere surrounding the corrosion-sensitive material. 7. Component arrangement according to claim 6, wherein the carrier (22) is designed as a plastic film. 8. Component arrangement according to one of the claims 6 or 7, wherein the Carrier (22) between an armature (8) and a pole tube (4) of an electromagnet (1) is formed. 9. component assembly according to claim 8, wherein the carrier (22) between the outer periphery of the armature (8) or one of the armature (8) associated Guide rod and the corresponding guide portion of the pole tube (4) is formed. 10. Component arrangement according to one of the claims 6 to 9, wherein the carrier is formed on a bearing bush made of plastic or composite material. 11. A component arrangement according to one of the claims 6 or 7, wherein an existing plastic or composite guide ring, for example, is designed for a piston rod or a piston of a hydraulic cylinder as a carrier. Page 10 of 10