DE19703489A1 - Process for applying an inorganic coating to an electrically conductive body - Google Patents

Abstract

This invention concerns a process for application of an inorganic coating to an electrically conducting body, particularly to a metal workpiece, said process involving precisely controlled temperature conditions with brief temperature shifts and economical and energy-saving operation. This process is characterized in that it first involves preparation of the body. Then the body is optionally degreased and/or pretreated chemically and/or sandblasted. Subsequently, a coating medium is applied to the body on at least the upper surface area to be coated. Then, at least the upper surface area of the body to be coated is inductively heated prior to and/or during and/or after bringing the coating medium to a reaction temperature. Finally, the coating medium is fully reacted for coating, whereupon the body is cooled.

Description

The invention relates to a method for applying an inorganic coating on an electrically conductive body, in particular on a metallic work piece.

The most varied of methods for applying an anorga are practical African coating on an electrically conductive body known. The structure the coating takes place under the influence of temperature, whereby a re action of the coating medium after its application to the body or Surface of the body is caused. The reaction leads to the build-up of an im essential inorganic network. Depending on the coating measure used Different reaction temperatures are required. Such a reak ions differ significantly from thermodynamics and kinetics Reactions with organic coating media. The coating described often serves to protect the often metallic body against corrosion. The above be Written reaction usually takes place in convection ovens after application of the loading layering medium. The reaction temperature is depending on the coating medium between 180 ° C and 300 ° C. The Be reacts at these temperatures coating medium for coating.

When using such convection ovens it is problematic that the heating process of the body to be coated is very sluggish, changing the temperature takes a lot of time. Due to the sluggish temperature curve, the The coating medium usually reacts in the surface area of the body the whole body is unnecessarily heated up due to heat conduction. By this co-heating of the entire body becomes a large amount of energy without Contribution to the reaction process needed.

Furthermore, it is disadvantageous when using the known convection ovens that it is explored derlich is to design the convection ovens so voluminous that the be layered body is completely absorbed in the furnace. Hence, that requires Implementation of the known coating process in an uneconomical manner a lot of space.

The present invention is therefore based on the object of a method for Application of an inorganic coating on an electrically conductive body  to specify, at which a precisely controllable temperature curve with short tempe temperature change processes in an economical and energy-saving mode of operation is possible.

The task outlined above is achieved by a method having the features of claim 1. According to this, a method for applying an inorganic coating to an electrically conductive body is characterized by the following method steps:
First, the body is made available. The body is then optionally degreased and / or chemically pretreated and / or blasted, for example sandblasted. As a result, the surface of the body can be prepared for the coating if necessary. This is followed by the application of a coating medium to at least the surface area of the body to be coated.

At least the surface to be coated is now in the manner according to the invention area of the body before and / or during and / or after application of the Be coating medium inductively heated to a reaction temperature. Because of this Inductive heating according to the invention is first of all a very energetic one advantageous heating of the body realized, since only the one to be coated Surface area and not necessarily the entire body is heated. Here become eddies by directly coupling to the electrically conductive body currents generated in the body due to the electrical resistance of the Body material cause the body to warm up. Energy losses through Er warm a heating medium in the form of, for example, circulating air and its inevitable Heat radiation is excluded here. The warming is consequently targeted in the body or in its surface area, whereby by a appropriate control of the induction device a precisely controllable temperature with the resulting short temperature changes is. The body is warmed up from the inside by the inductive heating, which also causes a highly efficient heating of the coating medium is.

The heating process according to the invention is summarized by means of an in ductive heating in a simple manner via the energy supply to the associated  Induction heating device adjustable, which is then due to the direct indukti ven energy transfer principle in addition to a short heating phase also extremely result in short reaction times to temperature control or change processes. Due to the direct heating of the surface area to be coated an economical and energy-saving mode of operation without the need for a extensive convection oven equipment realized.

Depending on the requirements specified by the coating medium, the coating surface area of the body in a simple manner before and / or during and / or after application of the coating medium to a reak tion temperature. This makes the process highly flexible guaranteed.

After the coating medium has reacted to form the coating, as last process step of the process according to the invention is the cooling of the body pers. The body can be exposed to room temperature, which ultimately results in an independent cooling of the body. The cooling can, however also by an active process step using a cooling medium respectively.

Consequently, the method according to the invention is an application method specified an inorganic coating on an electrically conductive body, in which a precisely controllable temperature curve with short temperature changes operations in an economical and energy-saving mode of operation.

With regard to a particularly flexible process, which individual requirement sufficient by the coating medium used, at least that could coating surface area of the body before applying the coating medium are inductively heated to a preheating temperature. The preheat temperature could avoid the premature initiation of the reaction of the coating medium are below the reaction temperature.

If necessary, the reaction of the coating medium to the Be stratification with the participation of water. This would be a separate feed Ren the amount of water required for the reaction is conceivable. The water supply  could, however, also be done in a simple manner by withdrawing what from the humidity of the surrounding atmosphere.

To protect the body against corrosion, the coating medium and thus the coating preferably contains pigments made of zinc and / or aluminum point. This would be an active protection against corrosion by the coating medium realized.

Depending on the requirements of the coating, the coating could Medium additives such as internal lubricants, viscosity regulators, flow have medium and / or anti-crater additives. An individual design possibility There are no limits to the coating medium.

In view of particularly favorable usage properties, the coating could tion medium a binder from at least one organic and / or inorganic have metal connection. Here are titanium, zirconium, chrome, boron, alumi Metal compounds containing nium, silicon, cobalt, nickel or magnesium particularly cheap. The aforementioned elements can be used individually in the metal connection or combined. It is also used as a binder for the coating medium a high molecular aminically crosslinked epoxy / phenoxy binder is advantageous.

With regard to a favorable course of the layer-forming crosslinking reaction could the binders in an optionally commercially available organic solvent solvent and / or dissolved in water. In the case of preheating the Kör pers could be the preheating temperature between room temperature and the boil temperature of the solvent or water. This would be a check lated escape of the solvent or water from which build up Layer guaranteed and thus achieved an optimal compression of the layer. A such preheating could be done both before applying the coating medium as well as after application. In the latter case, a stu by heating the surface area of the body to be coated already applied coating medium realized.

Since the heating of the body to be coated and the application of the loading layering medium could take place in two different parts of the system  in this case - when preheated before applying the coating medium Body - enough time after applying the coating medium the solvent or water to protect the surface below you Detect temperature while moving the body in the heating area can. Once the solvent has escaped, the temperature of the be layered surface to the required reaction temperature in a few seconds be brought to the optimum function and quality of the coating to reach.

With regard to a particularly favorable energy balance, inductive heating could of the body only within partial areas. Through such a targeted It is possible to heat only the areas to be coated, adjacent areas and / or hardly electrically conductive substances or surface areas to warm up little. A warming of these areas would then only be possible through heat conduction. The targeted introduction of heat further enables hin the coating on the one hand of individual parts of an overall device and others complete complete devices. Here, for. B. fully assembled Bearings can be coated as a whole or only at selected points.

Heating in a surface could be particularly energy-saving area with a depth of max. 0.5 mm. With a corresponding short-term Er Warming would be a heat conduction in remaining areas of the neglecting stratifying body.

To avoid heating not to be coated or temperature sensitive areas, the body could partially or totally during and / or after Warm with a suitable cooling medium. As a cooling medium could be a gaseous or liquid cooling medium in the form of, for example, air, water or oil can be used. This would make temperature-sensitive areas easy protected way from the effects of temperature. Only using the indukti ven warming, it is possible to identify temperature-sensitive areas or areas coating body simultaneously with the heating of the surface to be coated cooling areas with air or liquid cooling media.  

With such cooling it can be taken into account that the invention Processes with inductive heating shorten the response time with clear Increasing the crosslinking temperature to achieve a fully crosslinked coating tion conditionally, which only in their fully networked extent their favorable properties fully shows. Too high a temperature can destroy the Network or the pigments and additives embedded therein. Hence can cooling the body at the appropriate time has different positive effects bring. The cooling could only start after the reaction temperature has been reached be set.

With regard to a particularly high protective effect, the coating could have a ka have a thodic effect. Depending on the requirement, the coating could be additional Lich or alternatively to the cathodic effect electrically and / or thermally conductive be. Almost metallic conductivity could be achieved.

With regard to the smallest possible change in the dimension of the body applying the coating could make the coating a layer thickness of have about 2 to 30 microns. This would possibly be an extreme one Corrosion protection achieved in the thinnest layers. In a further advantageous way could the coating can also be weldable.

To avoid excessive environmental pollution, the coating could not Have heavy metals and in particular be free of chromium VI and cadmium.

The control of the layer thickness could, on the one hand, be based on the viscosity of the coating tion medium and on the other hand or additionally via a mechanical removal be set. With regard to mechanical removal, this could be in simple terms be done by spinning. All other known lacquer appliqués ons procedures are also applicable.

If necessary, an additional organic deck could be applied to the coating layer applied. The composition of the top layer could be considered on the best possible adhesion to the composition of the coating be true. The binder has a significant influence. Together  Hang with the application of organic cover layers are high molecular ami nically cross-linked epoxy / phenoxy binders of the top layer are particularly favorable.

The coating medium and / or the top layer are applied in be particularly simple way of spraying, in particular electrostatic loading spray, or a dipping process. The immersion process in connection with drainage This is particularly applicable to bulk goods.

In view of a particularly precisely controllable temperature curve, this could Heating and / or cooling or cooling take place under computer control. In order to a fully automatic procedure would be possible.

Controlling the coating parameters could be particularly simple by the alternating voltage frequency of the inductor and / or the induction duration and / or the reaction temperature.

The method according to the invention can be used with all known technologies.

Applying an organic cover layer can reduce the coloring, insulation, setting a constant coefficient of friction and improving contact serve corrosion resistance.

In particular, transistorized converters are used as induction devices because this is the execution of precise computer-controlled processes favor.

The inventive method for applying an inorganic coating tion has a high protective effect against chemical and electrochemical corrosion rosion as well as the contact corrosion of z. B. steel against aluminum. Of Another is a high resistance of the coating in salt spray, condensation and Kesternich tests achieved. A hydrogen embrittlement on the coated Surfaces do not appear.  

There are short cycle times of seconds while the process is being carried out possible. A decrease in component strength is due to the short temperature effect much less critical than with conventional heating.

With the method according to the invention one is due to the low energy costs and disposal costs realized extremely environmentally friendly process, the Building a small and compact system is possible.

There are now various possibilities for advantageously designing and developing the teaching of the present invention. For this purpose, reference is made to the subordinate claims, on the one hand, and to the following explanation of an exemplary embodiment of the method according to the invention with reference to the drawing. In connection with the explanation of the preferred embodiment of the method according to the invention with reference to the drawing, my preferred configurations and developments of the teaching are also explained in general. In the drawing, the
only figure in the context of a block diagram schematically the sequence of an exemplary embodiment of a method according to the invention for applying an inorganic coating to an electrically conductive body.

The single figure shows a schematic representation of the sequence of an exemplary method according to the invention for applying an inorganic coating to an electrically conductive body. The individual process steps are distinguished by the reference numbers 1 to 6 .

Reference number 1 denotes the first method step in which the body is made available. Process step 2 consists of facultative degreasing and / or chemical pretreatment and / or blasting of the body, for example sandblasting. If the body provided in step 1 no longer requires any further preparation, this method step 2 can be omitted.

In the next process step, identified by reference number 3 , a coating medium is applied to at least the surface area of the body to be coated. In this case, the coating medium could also be applied to surface areas of the body which are not to be coated, which would have the consequence of subsequently removing the coating medium from the surface areas which are not to be coated.

The subsequent inductive heating, identified by the reference number 4 , to at least the surface area of the body to be coated to a reaction temperature could take place before and / or during and / or after the application of the coating medium. Depending on the requirements, preheating to at least the surface area to be coated is possible before applying the coating medium. This could promote the escape of solvents that are not required in the crosslinking reaction of the coating medium.

The coating usually has a high thermal resistance up to approx. 350 ° C. Too high a temperature can destroy the coating. Too high Temperature, especially over a long period, is also sensitive to heat che areas of the body to be coated harmful, so that the short-term treatment development by means of induction is particularly advantageous here. In any case care must be taken to ensure that a maximum temperature is not exceeded.

Furthermore, it is only possible to use tem Temperature-sensitive areas of the body to be coated simultaneously with the Er cooling the coated areas with air or liquid media.

After the inductive heating, in step 5 the coating medium reacts for coating. Inductive heating enables a fully networked coating or protective layer to be formed quickly with less effort than conventional air-conditioning technology. This rapid reaction thermodynamics and kinetics require a significant increase in the crosslinking temperature in order to achieve a fully crosslinked layer which only has the stated properties to the full extent if the reaction time is shortened. Temperature control is advantageous because too high a temperature can destroy the network or the pigments and additives embedded in it.

In the last step of an embodiment of the method according to the invention, designated by reference number 6 , the body is cooled. This can be done on the one hand by passive cooling in, for example, ambient air or by active cooling using a special cooling medium such as water or oil.

Inductive heating is ideally suited for the reaction of the coating media on partially coated, more or less large bodies, to the freak tion coated body or for coating bulk goods tern. The method described is advantageous in that multiple uses Eliminate layers due to imperfections and contact points. Spraying before warmed bulk goods under movement of the fill guarantees with Beschich such a body a particularly uniform coating without defects.

When using a dipping process to apply the coating medium preheated bodies can also be immersed.

With regard to further advantageous refinements of the method according to the invention rens is used to avoid repetitions on the general part of the Be writing and reference to the accompanying claims.

Finally, it should be expressly noted that this was discussed above Embodiment of the method according to the invention only for the discussion of claimed teaching, but this does not apply to the embodiment limits.

Claims (28)

1. Method for applying an inorganic coating on an electrically conductive body, in particular on a metallic workpiece,
characterized by the following process steps:

• - providing the body;
• - if necessary, degreasing and / or chemical pretreatment and / or blasting of the body;
• - Applying a coating medium to at least the surface area of the body to be coated;
• - Inductive heating of at least the surface area of the body to be coated before and / or during and / or after the application of the coating medium to a reaction temperature;
• - Reaction of the coating medium for coating;
• - cooling the body.

2. The method according to claim 1, characterized in that at least the to coating surface area of the body before applying the coating medium is inductively heated to a preheating temperature. 3. The method according to claim 2, characterized in that the preheated temperature is below the reaction temperature. 4. The method according to any one of claims 1 to 3, characterized in that the reaction of the coating medium for coating with participation of water. 5. The method according to claim 4, characterized in that the water of the Humidity is extracted from the surrounding atmosphere. 6. The method according to any one of claims 1 to 5, characterized in that the coating medium pigments, preferably zinc and / or aluminum having.   7. The method according to any one of claims 1 to 6, characterized in that the coating medium additives such as internal lubricants, viscosity control rer, leveling agent and / or anti-crater additives. 8. The method according to any one of claims 1 to 7, characterized in that the coating medium is a binder of at least one organic and / or inorganic metal compound. 9. The method according to claim 8, characterized in that the metal compound titanium, zirconium, chromium, boron, aluminum, silicon, cobalt, nickel or magne has sium. 10. The method according to claim 8 or 9, characterized in that the bandage is dissolved in an organic solvent and / or in water. 11. The method according to claim 10, characterized in that the preheated temperature between room temperature and the boiling point of the solvent or the water. 12. The method according to any one of claims 1 to 11, characterized in that the body is only inductively heated within partial areas. 13. The method according to any one of claims 1 to 12, characterized in that heating in a surface area with a maximum depth of 0.5 mm he follows. 14. The method according to any one of claims 1 to 13, characterized in that the body partially or entirely during and / or after heating with a Cooling medium is cooled. 15. The method according to claim 14, characterized in that the cooling medium is gaseous or liquid in the form of, for example, air, water or oil.   16. The method according to any one of claims 1 to 15, characterized in that the coating has a cathodic corrosion protection effect. 17. The method according to any one of claims 1 to 16, characterized in that the coating is electrically and / or thermally conductive. 18. The method according to any one of claims 1 to 17, characterized in that the coating has a layer thickness of about 2-30 micrometers. 19. The method according to any one of claims 1 to 18, characterized in that the coating has no heavy metals and in particular chrome VI and is cadmium free. 20. The method according to any one of claims 1 to 19, characterized in that the layer thickness is adjusted via the viscosity of the coating medium. 21. The method according to any one of claims 1 to 20, characterized in that the layer thickness is set by mechanical removal. 22. The method according to claim 21, characterized in that the mechanical Removal is carried out by spinning. 23. The method according to any one of claims 1 to 22, characterized in that an additional organic cover layer is applied to the coating. 24. The method according to claim 23, characterized in that the together setting the top layer with regard to the best possible adhesion to the composition the coating is coordinated. 25. The method according to claim 23 or 24, characterized in that the Binder of the top layer is a high molecular aminically crosslinked epoxy / Phe is noxi binder.   26. The method according to any one of claims 1 to 25, characterized in that the application of the coating medium and / or the top layer over a Be spray, especially electrostatic spraying, or a dipping process. 27. The method according to any one of claims 1 to 26, characterized in that the heating and / or the cooling or cooling takes place under computer control. 28. The method according to any one of claims 1 to 27, characterized in that a control of the coating parameters by the AC voltage frequency of the inductor and / or the induction period and / or the reaction temperature follows.