EP0226011B1 - Apparatus for electrolytic treatment of printing cylinders - Google Patents

Description

The invention relates to a device for the galvanic treatment of printing cylinders with the features of the preamble of claim 1.

A device of this type is known from an earlier embodiment of the applicant and bears the type designation "Cr-jet master". The power is supplied via carbon brushes, which are in direct electrical contact with the quill between the two bearings of the quill. The consequence of this is that the sleeve, which is mechanically loaded by the holder of the pressure cylinder to be treated, is heated in the area of its storage and also the bearings themselves, by the power line and the friction of the carbon brushes on the sleeve surface, if the current load is not sufficiently limited. An enlargement of the cross section of the quill used for the electrical line is not possible due to the dimensioning of the electrolyte trough, if for printing cylinders with different diameters an optimal distance of approx. 40 mm to those on the inclined walls of the cylinder, even when treating printing cylinders with smaller diameters Electrode tub provided anodes should be observed.

• Fig. 1 eine schematische Querschnittsdarstellung der genannten vorbekannten Vorrichtung im Bereich der Lagerung und Stromzuführung,
• Fig. 2 eine Darstellung ähnlich der Fig. 1, jedoch mit der erfindungsgemässen Ausgestaltung der Vorrichtung,
• Fig. 3 eine im Vergleich zu Fig. 2 vergrösserte Querschnittsdarstellung der Vorrichtung im Bereich der Kohlebürsten,
• Fig. 4 eine in Richtung der Pinole gesehene Seitenansicht einer Bürstenhalterung,
• Fig. 5 einen Querschnitt durch die Bürstenhalterung nach Fig. 4 senkrecht zur Pinole und
• Fig. 6 einen Querschnitt durch die Bürstenhalterung nach Fig. 4 und 5 parallel zur Pinole.

The invention has for its object to find a device of the type mentioned, which avoids heating the quill in the area of its storage and which allows higher currents with low line losses. This object is achieved on the basis of the characterizing features of patent claim 1. Advantageous embodiments of the invention result from the following description with reference to the drawings and are the subject of the dependent patent claims. Show it:

• 1 is a schematic cross-sectional representation of the aforementioned known device in the area of storage and power supply,
• 2 shows a representation similar to FIG. 1, but with the inventive design of the device,
• 3 shows an enlarged cross-sectional view of the device in the area of the carbon brushes compared to FIG. 2,
• 4 is a side view of a brush holder seen in the direction of the sleeve;
• Fig. 5 shows a cross section through the brush holder of FIG. 4 perpendicular to the sleeve and
• Fig. 6 shows a cross section through the brush holder according to FIGS. 4 and 5 parallel to the quill.

A comparison between the representations of FIGS. 1 and 2 shows that the drive and bearing system of the device according to the invention can be designed essentially the same as in the older device of the applicant mentioned at the outset, so that this is only briefly explained on the basis of the schematic representations.

This drive and storage system for the galvanically treated pressure cylinder 1 is provided at one end of an elongated, not shown electrolyte trough 2, which receives the pressure cylinder to be treated. For the galvanic application of e.g. B. a copper layer on the circumferential surface of the pressure cylinder 1, several anodes are arranged in rows in the longitudinal direction of the electrolyte pan 2. The even rotation of the printing cylinder ensures a uniform build-up of the galvanic coating on the printing cylinder.

In order to establish the connection between the pressure cylinder 1 and the drive and bearing system, the inner housing 3, which can be moved back and forth like a ship and includes the drive and bearing system, is moved outwards together with the sleeve 4. H. shifted to the left in the illustration, so that the shaft journal 5 can be inserted into the centering shell 6 by lowering the pressure cylinder. However, this also requires a relative movement between the centering shell 6, which is held displaceably in the quill 4, with the centering tip 7 and the quill 4, so that the centering shell 6 projects in the axial direction over the electrical contact ring 8 by the length of the shaft journal 5. The inner housing 3 and thus also the sleeve 4 are then shifted again in the opposite direction until the electrical contact ring 8 comes into contact with the end face 9 of the pressure cylinder 1.

Pneumatic or hydraulic drive systems are available for the execution of these sliding movements, which can be combined with slide guides. The displacement of the inner housing 3 takes place by means of a cylinder-piston unit, the piston rod 10 of which is fastened to a carrier part 11 of the outer housing 12 which is firmly connected to the electrolyte trough 2 and to the cylinder 13 of which the inner housing 3 is fastened via its two supporting walls 14, 15. These mutually parallel supporting walls 14, 15 accommodate the bearings 16, 17 for the rotatable mounting of the sleeve 4, so that the sleeve 4 is axially fixed relative to the inner housing 3. The displacement of the centering 6 with the z. B. axially resilient centering tip 7 within the quill 4 takes place by means of a cylinder-piston unit, the piston rod of which is not visible in the illustration is firmly connected to a guide body 19 guided in the quill 4, which carries the centering shell 6 and the centering tip 7 and their cylinders 20 is connected to the inner housing 3 via an end connection block 21.

For the rotary drive of the quill 4 and thus the Printing cylinder 1, which is in drive connection with the sleeve via the electrical contact ring 8 and a sealing ring 23, is in the upper part of the inner housing 3 a on the support wall 14, z. B. electromotive rotary drive 25 is provided. The drive transmission from the rotary drive 25 to the sleeve bell 26 at the inner end of the sleeve 4 takes place, for example, by a toothed belt 27.

As far as described here, the construction of a device according to the invention according to FIGS. 2 to 6 can be carried out in the same way as the previously known device according to FIG. 1, so that the same reference numbers are provided.

The current supply to the pressure cylinder 1, on the other hand, takes place according to the prior art via the sleeve 4 by means of carbon brushes 30 which are in direct contact with it and which are arranged between the bearings 16, 17 provided for the sleeve 4 in the inner housing 3, so that the input mentioned disadvantages occur.

In the embodiment of the device according to the invention, the carbon brushes 32 are in the axial direction between the quill bearing 17 and the electrical contact ring 8, or on the outside on a support wall 15 of the inner housing 3 which projects outwards through the pressure cylinder 1 or the electrolyte trough 2 4 arranged so that the current path along the quill 4 to the end face 9 of the pressure cylinder is significantly shortened and heating and wear in the area of the bearing of the quill are avoided.

In an advantageous embodiment of this arrangement according to the invention, a current guide bushing 34 is also provided, which encloses the end region 33 of the quill, so that in this end region 33 too, a current conduction through the quill 4 mechanically loaded by the weight of the pressure cylinder 1 is avoided. In order to prevent the transmission of bending movements at the end area 33 of the sleeve 4, the current guide bushing 34 is preferably supported elastically on the sleeve 4 or at its end area 33. This is done, for example, by a radially supporting rubber ring 35 inserted between the circumference of the sleeve 4 and the current guide bushing, and by an axial connection, for. B. on the end face 36 of the quill 4, with the current bushing producing silent block-like, rubber-elastic device 37. This device 37 is formed, for example, by two rubber-elastic rings 38, 39 and an annular coupling body 40, which is form-fitting and by an adhesive connection or the like. connects both together. Axially directed, annular circumferential grooves 41, 42 in the current guide sleeve 34 and the sleeve 4 each take one of the rubber-elastic rings 38, 39 of the device 37, these rings 38, 39 or the like preferably in the grooves 41, 42 by an adhesive connection. are attached.

In order to prevent electrolyte liquid from getting into the inner housing 3 and thus to the drive and storage system as well as the power supply of the device, a sealing ring 44 is provided on the end of the current guide bushing 34 carrying the electrical contact ring 8 in addition to the sealing ring resting on the pressure cylinder 1 that slides resiliently against the corrosion-protected wall 45 of the inner housing. A cover ring 46 made of z. B. Plastic holds both sealing rings 23, 44 on the current guide bushing 34 and also serves to support the contact ring 8. In addition, the current guide bushing 34 is encased in the passage area through the wall 45 of the inner housing 3 by an electrically non-conductive protective sleeve 47, which serves to protect against corrosion. The seal is also necessary in order to prevent abrasion material from the carbon brushes 32 from reaching the surface of the printing cylinder 1 to be treated. A sealing ring 48 provided on the bearing 17 also protects it from abrasion particles of the carbon brushes 32.

Furthermore, a special cooling system can be provided to increase the current carrying capacity of the carbon brushes 32, as is shown in more detail in FIGS. 4 to 6. This has a channel system formed in a holding block 50 by a number of bores 51 to 55 running parallel and perpendicular to one another in the same plane, which is provided with an inlet and outlet connection 56, 57 for a cooling medium, for example water. The carbon brushes are in pairs on this holding block 50 with the largest possible contact surface 58 and are fastened by means of three continuous screws 69 and pressure plates 59, 60. Each pair of carbon brushes 32 is pressed by a bolt loaded by a spring (not shown), which engages with lateral play in a blind hole 62 provided centrally on the upper side of the holding block 50 and bears against the bottom thereof with a curved end face 63. The current is supplied by flexible stranded strands 64, 65 which are fixedly connected to the holding block 50 and, on the other hand, are electrically connected to a common conductor bar 66. The holding shaft 67 enclosing the pressure spring is also fastened to this conductor bar 66.

Claims (6)

1. An apparatus for the galvanic treatment of printing cylinders (1) in an electrolytic tank (2) with means (6,7,16,17,25 - 27) having a sleeve (4) mounted for rotation, for the mounting and rotational driving of the printing cylinder (1) and with a member (66, 64, 50, 32, 34) supplying current to an electric contact ring (8) supported by the sleeve (4), for contact with the end face (9) of the printing cylinder (1), characterised in that the carbon brushes (32) are arranged between the sleeve bearing (16, 17) and the electric contact ring (8).

2. An apparatus according to claim 1, characterised by a current-conducting bushing (34) surrounding the sleeve (4) over at least a part (33) of its length, the carbon brushes (32) being in electric contact with the peripheral surface of the current-conducting bushing.

3. An apparatus according to claim 2, charaterised in that the current-conducting bushing (34) is supported on the sleeve (4) by elastic components (35, 38, 39) arranged between them.

4. An apparatus acording to claim 3, characterised by at least one elastic rubber device (35, 37) each, supporting the current-conducting bushing (34) radially and axially.

5. An apparatus according to one of claims 1 to 4, characterised in that the carbon brushes (32) lie against a retaining member (50) having at least one cooling duct (51 - 55).

6. An apparatus acording to claim 5, characterised in that two carbon brushes (32) respectively encompass one cooled retaining block (50) between them.

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