EP1455006A1 - Method and apparatus for galvanizing components - Google Patents

Abstract

Process for galvanizing components with metallic coatings comprises moving the component to be coated through process stations using a gripper (20), and immersing in galvanic baths (29, 30). During immersion the position and/or orientation of the immersed component is changed by moving the gripper and the component is removed from the bath. An independent claim is also included for a device for carrying out the process.

Description

The present invention relates to a method and a device for galvanizing components, especially the galvanic production of metallic Coatings on fittings, preferably made of brass.

Large quantities of cast are used in the valve industry or pressed brass bodies. There are quantities of several for individual articles Hundreds of thousands a year are not uncommon. on the other hand is an important one for all manufacturers Part of the range in production only a little to rarely represented because of the diversity requirements and specific equipment of the range constantly increases.

The visual appearance and quality of the applied layers is one of the most important quality features of the products. The fittings are therefore for decorative purposes using galvanic processes different metal layers (Cr, Au, Pt). About the quality and variety of layers delimitation from competition also take place. Therefore the galvanic coating of the components one of the crucial manufacturing steps.

For the galvanic coating of the described Brass parts are practically used in all companies today conventional electroplating machines in the fittings industry used with electroplating frames. there all components are attached to racks (attached), which the components on the way through the Process container of the coating system free in the electrolyte hold and for power to everyone worry about each part. The racks are partial cycled back and forth in the electroplating bath.

Today, the frames are mostly populated by Hand (as is common in electroplating is). The racks are specific to individuals Components and component families designed and built. The parts of the frame that do not hold any components, are for protection against chemical attack and against Provide coating with plastic coatings. However, these become process fluids over time attacked, causing damage also the racks, which are then elaborate need to be repaired or replaced.

• bei der erreichbaren Spezifität der Beschichtungsparameter für die einzelnen Bauteile;
• beim Handhabungsaufwand für die sorgfältige Bestückung der Gestelle sowie das Abnehmen der beschichteten Bauteile.

There are two main disadvantages to this coating technique:

• the achievable specificity of the coating parameters for the individual components;
• in the handling effort for the careful assembly of the frames and the removal of the coated components.

• Die Bauteile müssen in einer solchen räumlichen Stellung in die Beschichtungsbäder und vor die dort angebrachten Anoden gebracht werden, dass eine möglichst ideale Stromverteilung erreicht wird. Nur so kann auch an allen Stellen des Bauteils eine Beschichtung in optimaler Qualität erzeugt werden. Dies kann je nach Bauteilgeometrie sehr schwierig sein, da es vor allem bei komplexen Geometrien Winkel und abgeschirmte Gebiete des Teils gibt, die nur sehr schwer in eine akzeptable Position gegen die Anoden gebracht werden können.
• Die Bauteile müssen so auf den Gestellen positioniert werden, dass sie beim Ausheben aus den Prozessflüssigkeiten möglichst schnell vollständig und rückstandsfrei auslaufen. Dies ist notwendig, damit es zu keinen Kontaminationen der Prozessflüssigkeiten durch mitgeschleppte Volumina aus den vorhergehenden Prozessstufen kommt und der Transport der Bauteile zur jeweils nächsten Prozessstelle möglichst schnell erfolgen kann.

The frames used must meet two requirements of coating practice in an ideal manner:

• The components must be brought into the coating baths and in front of the anodes attached in such a spatial position that the most ideal possible current distribution is achieved. This is the only way to create a coating of optimal quality at all parts of the component. Depending on the component geometry, this can be very difficult, as there are angles and shielded areas of the part, especially with complex geometries, which are very difficult to bring into an acceptable position against the anodes.
• The components must be positioned on the frames in such a way that they run out completely and without residues as quickly as possible when they are lifted out of the process liquids. This is necessary so that there is no contamination of the process fluids by entrained volumes from the previous process stages and the components can be transported to the next process point as quickly as possible.

These two requirements contradict each other in the Practice often, so that it is only partially realized can be. This either leads to losses in the coating quality or to an increased Error rate or at a great necessary effort for dishwashing technology to ensure residual contamination to be able to remove.

The application of the components to the electroplating frames is now mostly done by hand.

The frames differ in depending on the component their geometry, component arrangement and the necessary Movement of components for mounting on the frame. This is an automation of this process difficult. Automation, however, is important in today's manufacturing processes. Leave only with end-to-end automation the current demands on reproducibility and Documentability of the processes on the one hand and to the On the other hand, meet productivity. This automation is in the other manufacturing areas Part already quite advanced, e.g. can Today, components are ground almost fully automatically and be polished.

So there is still no flexible concept for one today Handling technology covering the wide range of articles in the fittings industry and could cover itself easily connect with the coating technology leaves.

In summary, the conventional procedure can be summarized so that components, in particular Fittings or attachments and the like, in large electroplating machines are coated, for which all Components applied or attached to frames the components on the way through the Process container of the coating system free in Keep electrolyte and power supply in everyone worry about each part. The assembly of the racks is done by hand.

In contrast, industrial robots are used in the remaining production for handling the components in the processes Grinding and polishing used. The feeder too the components to the individual stations or the respective transfer between the individual stations takes place automatically.

The break in the logistic chain between polishing and electroplating creates considerable difficulties in the passage of the components. Because it will here from a single part production to a batch production passed. Because the big electroplating plants always driven with minimum quantities of certain components to be of high quality, the logistic concepts of component processing are right and the electroplating do not match.

Here is the present invention Task, a method and an apparatus available to provide with which also individual components or small lot sizes with a significant reduction in Process time can be galvanized.

This object is achieved by the method according to claim 1 and the device according to claim 12 solved. advantageous Developments of the method according to the invention and the device according to the invention given in the respective dependent claims.

According to the present invention, a to be coated Component picked up individually by a gripper and immersed in the galvanic bath. critical is now that during the electroplating process the position and / or orientation of the submerged component in a predetermined manner is changed by movements of the gripper. On this way it is possible to have any shape Placing the component in a galvanic coating bath, being an ideal during coating Position opposite the anodes. hereby it is possible to build components from a wide range Process spectrum with only minor conversions and to supply a galvanizing unit. In particular it is beneficial that by changing the spatial orientation of the components during the galvanic Coating the distribution of electrical Felling lines during the coating process can be influenced. This allows specific, predetermined layer thickness distributions on the Achieve component.

By picking up the component with a gripper it is still possible to connect the component to the Remove coating process from the bath and then realigned with the objective that the Bath liquid completely from the component or the component expires. Here, too, is advantageous position while the component drips and / or location of the component changed to really to let out all cavities etc.

Another advantage of the present invention is that the components can now be coated at very high current densities, which are, for example, a factor of 10 higher than usual. For example, current densities of up to 100 A / dm ² can be achieved in a Watts nickel electrolyte which is operated conventionally at 3 to 5 A / dm ² .

The handling system, for example an industrial robot can not only through the components lead the electroplating process, but also through all Process stages used to manufacture the component to lead. Since usually only individual components be taken, but it is also possible is, with suitable grippers several components at the same time to grasp is the galvanization of very small lots, for example less than 10 components, economically possible. Due to the individual orientation of the components is avoided that at high Current densities commonly encountered problems with the layer quality can be avoided because the coating can be controlled in a targeted manner.

The gripper is advantageously used for fine control the position of the component with an image processing system for position detection of either the gripper and / or the component.

With the present invention, fittings can or parts of fittings very quickly, for example within 1 to 2 minutes instead of conventional 15 minutes, and with high and reproducible Quality can be electroplated. At the same time, the handling system according to the invention linked to automated manufacturing so that manual assembly processes that often errors are avoided.

The one used according to the invention advantageously transmits Grab the current on the ones to be galvanized Components. It can also have an outlet for air with which air, e.g. as sealing air on which Components can be transferred. Also an outlet for Liquids, such as water, to the gripping point, for example for rinsing purposes, can on the Grippers may be provided.

Particularly advantageous movements of the component concern a rotation about an axis, if any can be endless, panning around two more axes or a movement in three on top of each other vertical spatial axes within the galvanic Bath. The movements should be complete be arbitrary and controlled so that the movement is started or stopped at any time can be. So it is then also possible to move the gripper with other processes in the coating reactor, for example, adding Anode segments or a change in bath flow to synchronize. The coating flow, i.e. its strength, can with such changes in Coating reactor can be synchronized.

The area of the anode, which is closest to the component, during the Process by changing the position of the component be varied, as well as the distance between the Component and the anode.

By means of a directed flow in the used Electroplating bath can be caused at certain Dividing the component by appropriate positioning the component a higher mass exchange with the Electroplating bath for the deposition of a higher layer thickness provides.

The following are examples of devices according to the invention and procedures given.

Fig. 1

einen Greifer;

Fig. 2

eine Galvanisieranordnung; und

Fig. 3

die Anordnung von Anoden in einem Galvanisierbad.

Show it:

Fig. 1

a gripper;

Fig. 2

an electroplating assembly; and

Fig. 3

the arrangement of anodes in an electroplating bath.

Fig. 1 shows the schematic diagram of a gripper 20, the is suitable for the present invention. With the in 1 grippers 20 can be rotationally symmetrical Components are included and on this Electricity for the coating process in a galvanic Bad be transferred. Furthermore, the Gripper 20 the rotation of the gripped component.

The gripper 20 has a housing 2, which on a Housing attachment 1 is attached. This housing has an opening from which the actual gripping element protrudes downwards. This opening is rotationally symmetrical and via a shrink tube 9 sealed. There is one in the housing itself conventional arrangement of a robot gripper with a Air distributor 3 and an inner part 3a of the air distributor, via the compressed air for turning and actuating of the gripper is fed to the gripper. Farther is centrally symmetrical within the Housing 2 and the opening penetrating a plunger 4 with plunger extension 8, which in turn has an inner bore 18 have a flushing medium between the jaws 14 of the chuck of the gripper can be introduced. This feed line 18 goes over into a channel 12 for the flushing medium, which is extends axially symmetrically within the ram. At the End of the plunger, outside of the housing 2 are mentioned jaws 14 arranged. These are from surrounded an adapter sleeve 10. Via a threaded bolt 11 is the clamping sleeve 10 by means of the plunger 8 movable up or down. Since the chuck 14 and the adapter sleeve 10 has complementary bevels, these bevels slide when the adapter sleeve is moved 10 against each other, so that the chuck when starting up the clamping sleeve 10 narrows and thereby Component that in this case is rotationally symmetrical should be, can take. When pushing back the Clamping sleeve 10 give way to the clamping jaws of the chuck 14 apart so that by such a movement a seized component released again becomes. The movement of the adapter sleeve relative to the chuck is by the threaded bolt 11 and an axial Movement of the plunger 4, 8 causes.

Both the chuck 14 and the collet 10 have openings or openings 16 and 15, with which the introduced via the flushing medium channel 12 Flushing medium can flow out.

Fig. 2 shows a galvanizing arrangement in which a gripper according to FIG. 1 can be used. The Gripper 20 is located at the end of a robot arm 21 of a robot 22. The robot arm is telescopic extendable and on the other hand rotatable around its storage. A robot entry station 25 and surround the robot 22 various degreasing baths 26, the first Rinse 27a, for pickling 28, for the second rinse 27b, for electroplating with nickel 29, for the third Rinse 27c, for electroplating with chrome 30, for the fourth Rinsing 27d, for drying 31 and a station 32 to discharge the component.

The robot now grips components that, for example are delivered in a special pallet in the Station 25 for introducing components and moving them using a predetermined program by the different process stations 26 to 31. The current parameters like the movement of the component by rotation and / or panning or other movements completely predefined in the robot program and coordinated.

Grasping and contacting each Component takes place via a possibly special adapted to the geometry of the underside of the component Gripper, as shown for example in Fig. 1 is. The material of this gripper 20 is selected so that that on the one hand he has the necessary electricity the component can transfer, but on the other hand the withstands various aggressive process media. He is still designed to fit into the Rinsing baths 27a to 27d can be easily rinsed so that the gripper does not contaminate the subsequent ones Process fluid resulting from carryover. This can be done, for example, by coating all not used for power transmission to the component Components of the gripper 20 with a hydrophobic chemical-resistant polymer layer reached become. In the design of the gripper 20, it is still essential, as few columns or To create undercuts to drain the To facilitate the gripper.

In the method according to the invention are now in the Coating baths 29 and 30 very much higher currents used as in a normal electroplating process it is possible. This is possible because that Component suitably arranged opposite the respective anodes can be. So the process time of the whole Coating process in this example approx. 10% of the conventional process time can be reduced.

3 shows an example of an arrangement of anodes, as they are for coating one shown in Fig. 3 Component 19 are suitable. They are parallel to each other Main anodes 40 are provided, by means of which the essential parts of the component 19 are coated. Furthermore, below the component 19 in the Areas in which there are recesses or angles in the component, special anodes 41 are arranged, those for a coating also in these recesses to care. The special anodes 41 are via a line 42 connected to a power source. Farther 3 is the polarity of the respective anodes 40, 41 and the component 19 shown.

With the anode arrangement shown in Fig. 3 can hence the acute angles of the recesses are sufficiently coated in the component 19. Using only the main anodes there, for example, only a layer thickness of 1 µm reached while on the outer surface of the component was 12 to 15 µm. By using the Additional anodes 41 was the field line distribution in the shielded angles or recesses improved so that there is a sufficient layer thickness up to 3 µm was deposited.

Claims (22)

Method for galvanizing components (19) with metallic coatings in a galvanic bath (29, 30), characterized in that the component (19) to be coated is picked up individually by a gripper (20) into the galvanic bath (29, 30) immersed, the position and / or orientation of the immersed component (19) is changed in a predetermined manner by moving the gripper (20) during the immersion and finally the component (19) is removed from the galvanic bath (20). Method according to the preceding claim, characterized in that the immersed component (19) is rotated, pivoted and / or the position is changed with respect to the three spatial axes. Method according to one of the preceding claims, characterized in that the immersed component (19) is rotated continuously at least temporarily around one or more predetermined axes. Method according to one of the preceding claims, characterized in that the position and / or orientation of the immersed component (19) with respect to the anode (40, 41) of the galvanic bath (29, 30) is changed in a predetermined manner. Method according to the preceding claim, characterized in that the distance of the immersed component (19) from the anode (40, 41) of the galvanic bath (29, 30) is changed. Method according to one of the preceding claims, characterized in that the component (19) after removal from the galvanic bath (29, 30) in a spatially and / or with respect to the duration predetermined position or sequence of positions for the leakage of remaining bath liquids from the Component is positioned. Method according to one of the preceding claims, characterized in that current, air and / or water is transferred to the component (19) in a predetermined manner via the gripping device (20) during immersion and / or dripping. Method according to one of the preceding claims, characterized in that the current transmitted to the component (19) is changed in a predetermined manner. Method according to the preceding claim, characterized in that the current transmitted to the immersed component (19) is changed as a function of the position and location of the component (19). Method according to one of the preceding claims, characterized in that during the immersion of the component (19) in the galvanic bath (29, 30) an optionally variable liquid flow is generated in a predetermined manner. Method according to one of the preceding claims, characterized in that, during the immersion of the component (19), different anodes (40, 41) with different distances from the component (19) and / or different shapes in different numbers are switched on or off in a predetermined sequence become. Device for galvanizing components (19) with metallic coatings with at least one galvanic bath (29, 30), characterized by a gripper (20) for gripping a component (19) to be galvanized, immersing the component (19) in the galvanic bath ( 29, 30), holding the component (19) in the bath (29, 30), and removing the component (19) from the bath (29, 30), the gripper (20) with the component (19) during the Diving is displaceable, pivotable and / or rotatable in a predetermined manner, and
a motion control device for controlling the movement of the gripper during diving in a predetermined manner. Device according to the preceding claim, characterized by a robot (21, 22) or robot arm (21) for moving the gripper. Device according to one of the two preceding claims, characterized in that the gripper (20) after removal of the component (19) from the bath (29, 30) can be moved by the control device in a predetermined manner for dripping. Device according to one of claims 12 to 14, characterized by a voltage source connected to the gripper (20) for transmitting current to the component (19) via the gripper (20). Device according to the preceding claim, characterized by a current control device for controlling the current transmitted to the component (19) in coordination with the movement control device. Device according to one of claims 12 to 16, characterized in that the gripper (20) has an outlet for compressed air for applying compressed air to the component. Device according to one of claims 12 to 17, characterized in that the gripper has an outlet (13) for liquids, in particular water, for loading the component (19) with liquid. Device according to one of claims 12 to 18, characterized by a plurality of differently arranged and / or differently designed anodes (40, 41) in the galvanic bath (29, 30), which can be switched on and / or off individually or in groups in a predetermined manner , Device according to one of claims 12 to 19, characterized in that the movement control device and / or the current control device, the position and / or location of the component (19) in the galvanic bath (29, 30) and / or the applied current in accordance with the connected anodes (40, 41) controls. Device according to one of claims 12 to 20, characterized by a device for generating a predetermined directed flow of the liquid in the bath (29, 30). Use of a method or device according to one of the preceding claims for Coating of fittings, sanitary fittings, in particular fittings made of brass with metals or metal alloys, with chrome, gold, platinum or alloys thereof.

Images