DE19735244B4 - Method and apparatus for the chrome plating of workpieces - Google Patents

Abstract

method for the simultaneous chrome plating of introduced into an electrolyte bath Verchromungsflächen several workpieces, the workpieces (21) are electrically contacted on the cathode side, wherein the chrome plating surfaces (21.1) with the formation of equal potential surfaces opposite a flat surface Anode (12) are held, and wherein the workpieces (21) on the anode side by a diaphragm (23) passed be, wherein by means of the diaphragm (23) to the chromium plating surfaces (21.1) subsequent surface areas of the workpiece (21).

Description

was standing of the technique

The The invention relates to a method for chromium plating of chromium plating surfaces Workpieces, the workpieces electrically contacted on the cathode or anode side and on the anode side or be passed through a diaphragm on the cathode side, wherein by means of the diaphragm adjoining the Verchromungsflächen surface areas of the workpiece be covered, and wherein the chromium plating surfaces placed in an electrolyte bath become. Furthermore, the invention relates to a device for chrome plating.

at known devices for chromium plating, multiple apertures are used, which are provided with holes. The bore cross section corresponds while the outer dimensions of the workpiece. In the strip-like aperture, the holes are in a row and evenly to each other spaced apart.

Multiple panels can be attached to a support frame. The rows of holes are aligned vertically. In the immersion bath, an anode is present, which is arranged approximately at the level of the central region of a diaphragm. It has been found that the individual workpieces that are held by the panel, have different chrome plating qualities. In particular, the workpieces, which were held in the beginning and end of the series of holes, are coated only with a chromium layer of small layer thickness. Such a device is for example in the DE 44 19 984 C2 described.

Farther is from the article R. Rolff "Dependence the layer thickness of the depth of the electrolyte in the galvanic Metal Deposition "Electroplating, 80 (1989) No. 8, pp. 2615-2621, a device for the coppering of printed circuit boards, at which is between a flat Anode and a flat Cathode is located a string aperture. This leads to a more even Coating of printed circuit boards.

Out V. Klapka "The Hard chrome plating of cavities ", electroplating, 84 (1993) No. 4, pp. 1182-1186 is a chromium plating device known in which for deposition uniform surface layers Auxiliary anodes are used.

Furthermore is from L. Flögel, L. Boone "continuous flow system for horizontal through-contacting of printed circuit boards ", Galvanotechnik, 79 (1988) No. 3, pp. 905-910 a method of electroplating vias of printed circuit boards in which the electrolysis cell is constantly purged with electrolyte.

advantages the invention

It Object of the invention, a method and an apparatus of the mentioned in the beginning To create kind, whereby a dimensionally accurate Chrome plating of workpieces possible is.

These The object of the invention is achieved in that the chrome plating under Formation of equal potential levels opposite the area-trained Anode be kept.

As a result this procedure is between the anode and the cathode forming chromium plating surfaces a capacitor-like Streamline field created. This ensures that all surfaces are evenly energized become. This will give a uniform chrome application on all workpieces possible, so that a true to size and reproducible chrome plating becomes possible.

According to a preferred embodiment variant of the invention, it is provided that the workpieces are arranged with their chromium plating surfaces transversely to the flow direction of the electrolyte. In particular, if the flow direction of the electrolyte is vertical, the individual workpieces can be arranged horizontally next to one another. With this measure, it is ensured that the hydrogen forming during the chromium plating process does not adhere to the chromium plating surfaces and hampers the chromium plating here. Furthermore, due to high current speeds, current densities above the conventional range (about 50 A / dm ² ) can be applied. In particular, this allows short cycle times during chrome plating to be realized.

Around a uniform distribution To reach the streamlines, it may be provided that by means of the panel the chrome plating surfaces the individual workpieces evenly to each other spaced, are held in a matrix. This can be under achieve a high packing density of the workpieces.

to Generation of a uniform, as possible homogeneous flow, provides a variant of the invention, that the chrome plating surfaces of workpieces the electrolyte over an influx extension the aperture is fed, and that the supplied electrolyte via a Drain channel of the workpiece and / or one formed between the diaphragm and the workpiece Outflow channel is derived. The uniform flow generated by this measure make sure that no Dead water zones arise in which gas bubbles, for example Hydrogen enriches.

A inventive device may for example be characterized in that the chromium plating surfaces in an inflow chamber held in which electrolyte is supplied to them, that in the inflow chamber a flat formed anode is arranged opposite the chrome plating surfaces, and that the Chrome plating surfaces on are held at the same potential levels. The inflow chamber forms a closed system in which the streamlines are parallel, bundled between the anode and the cathode.

There only the surfaces to be chrome plated the workpieces in the inflow chamber protrude, this can be form with a correspondingly small volume.

The Device can be then use it effectively in terms of production, if it is provided that the inflow chamber is completed with a cover holding the aperture, the fortifications over exchangeably connected to the inflow chamber is, and that on the attachment a holder is centered on a base body workpieces wearing. With these simple measures is a flexible system created, which depends on the particular to be chromed workpieces different apertures can be used. The workpieces themselves are attached to the holder. They are through the breakthroughs passed in the aperture, which is facilitated by the centerings. This allows the holder also be applied by machine to the attachment.

advantageously, it may be provided here that the body centering bears that in, with insertion chamfers provided centering recordings of the essay are insertable, and that the insertion movement of the centering in the centering by means of a stop is limited.

A additional Fixation of the workpieces the holder is reached when the workpieces are in the area between the Holder and the panel are secured by a stabilizer.

The Invention will be described below with reference to one, shown in the drawings embodiment explained in more detail. It demonstrate:

1 in side view and in section a schematic representation of a treatment module of a chrome plating plant,

2 in an enlarged view a section of the chrome plating according to 1 .

3 in side view and in section, with the system according to 1 and 2 chrome-plated workpiece and

4 another, with the chrome plating according to the 1 and 2 chrome-plated workpiece.

The 1 shows a treatment module of a chrome plating device, which represents a partial segment of a Verchromungsstraße. In this chrome plating line, the chrome plating device is embedded between pretreatment and aftertreatment baths.

The chrome plating device has a container 16 in which an electrolyte 17 is stored. In the container 16 is a support member set, which is an inflow chamber 10 encloses. The inflow chamber 10 is from the vertical walls 11 limited. In the lower part of the inflow chamber 10 is a plate-like anode 12 brought in. The anode 12 has a permeable grid structure. It is conductive to a current contact 15 connected outside the container 16 is held. Below the anode 12 forms the inflow chamber 10 a distribution room 13 , This has the task of a homogeneous velocity profile of the electrolysis solution over the cross section of the inflow chamber 10 to create. At the top is the inflow chamber 10 with an essay 20 completed. The essay 20 is from a holder 30 covered, several workpieces 21 holds. On the detailed design of the essay 20 and the owner 30 will be discussed in more detail later. The individual workpieces 21 are at a cathode 31 electrically coupled.

In order to prevent electrolyte in the form of aerosols are deposited in the environment, are separators 19 used. The separators 19 are at suction 18 connected. This allows the aerosols in the separator 19 imbibe. The separated electrolyte is separated out here and into the container 16 recycled. In the 2 are the tower 20 and the holder 30 shown closer. As can be seen from this illustration, forms the inflow chamber 10 a flat surface on which the essay 20 fitted and by means of a circumferential seal 28 is sealed. For fixing the attachment 20 at the inflow chamber 10 are glands 14 intended. The essay 20 wears a visor 23 , This is plate-like and horizontally arranged. Due to their horizontal arrangement is the aperture 23 parallel to the anode 12 , The aperture 23 has a variety of openings 25 on, which are arranged spaced from each other at the same pitch. The breakthroughs 25 are arranged in rows, which run in the direction of the image depth. This results in a matrix of openings. Both to the inflow chamber 10 as well as to the top of the iris 23 there are the openings 25 expanded by chamfering. The inflow chamber 10 facing bevel bil det thereby a Zuströmerweiterung 26 , The inflow chamber 10 Averted bevel serves as an introduction aid 24 for the workpieces 21 ,

The breakthroughs 25 are presently designed as cylindrical bores, which in their dimensions to the cross section of the workpieces 21 adapted trained.

On the tower 20 can the holder 30 put on. The holder 30 has a basic body 31 , on which several fixing elements 32 are held. The fixing elements 32 are designed here as magnets. These magnets are from a plate 33 covered. The plate 33 is with the main body 31 screwed. In the fixing elements 32 turned away side of the plate 33 are grooves 21.3 incorporated, which extend in the direction perpendicular to the image plane. On the plate 33 let the ferromagnetic workpieces 21 put on; they are made by means of fixing elements 32 held at this. The workpieces 21 are from a drainage channel 21.2 imbued with a spatial connection between the grooves 21.3 and the inflow chamber 10 creates. The plate 33 is about a contact part 40 connected to the cathode. About this connection, the individual workpieces 21 placed on the same reference potential.

Between the plate 33 of the owner 30 and the aperture 23 is a stabilizer 35 arranged. The stabilizer 35 has a plate-like shape and is provided with a hole pattern. Through the individual holes of this hole pattern are the workpieces 21 plugged. This offers the stabilizer 35 a tilt protection, on which the workpieces 21 can lean against.

To get between the holder 30 and the tower 20 to be able to keep a fixed distance is a stop 34 used to the holder 30 is coupled. The stop 34 is formed by a sleeve-shaped part on a centering pin 34.2 is deferred. The centering bolt 34.2 is about a fixing screw 34.4 to the holder 30 screwed. The centering bolt 34.2 can in a centering shot 22 of the essay 20 be introduced. As an assembly aid here is a Einführfase 34.3 , Depending on the dimensioning of the attachment 20 or the holder 30 are two or more centering bolts 34.2 used.

The in the 2 illustrated situation shows the chrome device in the ready state. Accordingly, the workpiece is 21 through the breakthrough 25 the aperture 23 pushed through. In the process, the dimension that is the workpiece 21 through the breakthrough 25 through into the inflow chamber 10 protrudes through the stop 34 and the distance ratio between the surface of the plate 33 of the owner 30 and the aperture 23 certainly. The in the inflow chamber 10 protruding surfaces of the workpiece 21 form the chrome plating surfaces 21.1 , Accordingly, the breakthrough borders 25 the surface areas of the workpiece 21 off, which should not be subjected to a chromium layer. In the illustration according to 2 For reasons of clarity, it is only a single workpiece 21 shown. However, it can be seen that according to the number of openings 25 in the aperture 23 several workpieces 21 from the holder 30 can be worn. The chrome plating surfaces 21.1 the individual workpieces 21 lie on about the same potential levels. This potential plane is parallel to the anode 12 aligned. Because the anode 12 over the entire cross section of the inflow chamber 10 extends, a kind of current well is formed, in which the Stromflußlinien are aligned substantially parallel and between the anode and the Verchromungsflächen 21.1 run. As a result of this even current distribution can be a true chrome plating of the chromium plating 21.1 respectively. For chromium plating, the electrolyte 17 by means of a suitable Pumpenmechanismusses in the manifold 13 introduced and evenly distributed here. Following the distributor 13 flows through the electrolyte 17 the anode 12 and is through the inflow chamber 10 through the chrome plating surfaces 21.1 the workpieces 21 fed. There the electrolyte causes 17 due to metallic deposits a chrome plating. Chrome plating produces hydrogen. Due to the horizontal orientation of the aperture 23 and supported by the influx extension 26 This hydrogen is continuously fed to the electrolyte through the drainage channel 21.2 of the workpiece 21 removed. The electrolyte 17 gets after it has the drainage channel 21.2 happened in the groove 21.3 , From here it can be returned to the container 16 flow away.

After the chromium plating, the holder can 30 from the tower 20 lifted and placed in a subsequent rinse. Because the workpieces 21 only to a small extent with the electrolyte 17 come into connection, the rinsing process is correspondingly less expensive. In the 3 and 4 are two possible variants of a workpiece 21 shown, which can be chrome plated with the previously described chromium plating device. With the arrow F is the flow direction F of the electrolyte 17 indicated. Of the 3 can be seen that even intricately designed inner walls within a workpiece 21 can be chrome plated. For this purpose, only attachment parts are to be used, which are not to be chromed inner surfaces of the workpiece 21 cover.

As 4 illustrated, complicated edge jumps can be chrome plated inside a hole.

Claims (10)

Method for the simultaneous chrome plating of chromium plating surfaces of a plurality of workpieces introduced into an electrolyte bath, wherein the workpieces ( 21 ) are electrically contacted on the cathode side, wherein the chrome plating surfaces ( 21.1 ) with the formation of identical potential surfaces opposite a flat anode ( 12 ) and the workpieces ( 21 ) on the anode side through a diaphragm ( 23 ), whereby by means of the diaphragm ( 23 ) to the chrome plating surfaces ( 21.1 ) subsequent surface areas of the workpiece ( 21 ) are covered. Method according to claim 1, characterized in that the workpieces ( 21 ) with their chrome plating surfaces ( 21.1 ) transverse to the flow direction of the electrolyte ( 17 ) to be ordered. Method according to claim 1 or 2, characterized in that by means of the diaphragm ( 23 ) the chrome plating surfaces ( 21.1 ) of the individual workpieces ( 21 ) evenly spaced from each other, are held like a matrix. Method according to one of claims 1 to 3, characterized in that the chromium plating surfaces ( 21.1 ) of the workpieces ( 21 ) the electrolyte ( 17 ) on an inflow extension ( 26 ) the aperture ( 23 ) and that the supplied electrolyte ( 17 ) via a drainage channel ( 21.2 ) of the workpiece ( 21 ) and / or one between the diaphragm ( 23 ) and the workpiece ( 21 ) is derived. Device for simultaneous chrome plating of chrome plating surfaces of several workpieces, wherein the workpieces ( 21 ) are electrically conductively connected to a cathode on the cathode side, wherein a surface formed anode ( 12 ) the chrome plating surfaces ( 21.1 ) is arranged opposite, so that the chrome plating surfaces ( 21.1 ) are held on the same potential surfaces, wherein the chrome plating surfaces ( 21.1 ) in an inflow chamber ( 10 ), in which electrolyte is supplied to them, and wherein the workpieces ( 21 ) on the anode side through a diaphragm ( 23 ) are guided, wherein by means of the diaphragm ( 23 ) to the chrome plating surfaces ( 21.1 ) subsequent surface areas of the workpiece ( 21 ) are covered. Device according to claim 5, characterized in that the diaphragm ( 23 ) transverse to the inflow direction of the electrolyte ( 17 ) with mutually uniformly spaced openings ( 25 ), which are adapted in their dimensions to the part of the workpiece to be performed, and that the workpieces a flow channel ( 21.2 ) for the electrolyte ( 17 ), or that between the workpiece ( 21 ) and the opening ( 23 ) is left as serving as a drainage space. Apparatus according to claim 6, characterized in that the diaphragm ( 23 ) at the openings ( 25 ) chunky influx enhancements ( 26 ), which, starting from the openings ( 25 ) in the inflow direction for the electrolyte ( 17 ) expand. Device according to one of claims 5 to 7, characterized in that the inflow chamber ( 10 ) with one, the aperture ( 23 ) essay ( 20 ), which has fortifications ( 14 ) exchangeable with the inflow chamber ( 10 ) and that on the essay ( 20 ) a holder ( 30 ) which can be centered on a base body ( 31 ) the workpieces ( 21 ) wearing. Apparatus according to claim 8, characterized in that the basic body ( 31 ) Centering pins ( 34.2 ), which in, with Einführfasen ( 34.3 ) provided centering recordings ( 22 ) of the article ( 20 ) are insertable, and that the insertion movement of the centering pins ( 34.2 ) in the centering recordings ( 22 ) by means of a stop ( 34 ) is limited. Device according to one of the preceding claims, characterized in that the workpieces ( 21 ) in the area between the holder ( 30 ) and the aperture ( 23 ) by means of a stabilizer ( 35 ) are secured.