DE603910C - Process for the galvanic production of metal deposits - Google Patents

Description

The invention relates to a method ■ for the galvanic production of metal deposits, ζ. Β. Silver, gold, nickel, chrome, etc. Precipitates, from an electrolyte usual composition.

The purpose of the invention is to increase the current density compared to the previously used To enable maximum values and thus shorter working hours than before without the Precipitation quality suffers, even better precipitation with higher current density and without power loss.

The same goal is sought in a known method in which the electroplating current is alternately switched on and off again, so that in the switch-off times that in the switch-on times by polarization voltage difference between the electrodes and preventing the further passage of current Seeing the electrodes can to some extent even out through the bath. However, the bath offers considerable resistance to this compensation, so that it is only slowly and runs asymptotically. This has the consequence that the compensation is not fast enough and in times that come into practical consideration is only very incomplete, so that at Switching on again is a considerable obstacle to the passage of electricity with energy losses, there is a potential due to the polarization of the electrodes. The aim of the invention is therefore not reached in this way.

The shortcomings of this known method are addressed in another known method accounted for by the fact that the working current alternates in the one and in the opposite direction Direction is sent through the bathroom. When the current is reversed, the disruptive polarization formed during electroplating is indeed reversed, but only through the expenditure of electricity without useful power, so that this method causes considerable losses in operation brings with it. In addition, it is expensive to carry out mechanically driven commutator required.

The invention makes the working current alternate from the former known method off and on again, while avoiding the disadvantages of both of the methods mentioned, use and looks for this purpose suggests that in the meantime, in which the working current is switched off, that by polarization Potential generated by short-circuiting the anode and cathode of the electroplating cell is brought to automatic compensation. This compensation can accordingly make the difference compared to the known methods very quickly and without loss of time and power go yourself.

The invention enables a much higher current density than usual, for example the 6- to 8 times the current density, which would otherwise be used in a bath of the same composition for the Creation of an appropriate precipitate to avoid known evils at most

is usable. This increase in the current density not only reduces the time lost, the caused by the work breaks or the shutdown periods of the working current, balanced, but, moreover, the total time required for the production of a precipitate Thickness is necessary on a specific object in a specific built cell, quite considerably reduced, as will be described in ίο an embodiment target. Moreover, the precipitate produced according to the invention is not only perfect pore-free, but even of a finer structure than a known way with a steady working current and lower current density produced precipitate and has a particularly shiny appearance. This brings the further advantage that the following on the galvanic production of the deposit Work steps can be partly saved and yet high gloss of the with precipitation provided object is achieved. For example, does the method according to the invention With silver plating, scratching the object before oxidizing or polishing is superfluous.

According to a preferred embodiment of the method according to the invention, the training is and preferably automatically switching on or short-circuiting at regular time intervals caused by electrical or electromagnetic switching devices. This can be done by a switching device switching off or switching on the working current makes at the same time in which 'another the short-circuit connection establishes or interrupts. Instead, for the sake of simplicity, one and the same Switching device off or on the working current and at the same time the short-circuit connection establish or interrupt.

As switching devices can, for. B. commercial mercury interrupter tubes or others Interrupters are used, one of which is in the working circuit and, if necessary, another in the short-circuit line is. The control coils for the mercury interrupter tubes 0 of the invention preferably switched in flashing circuit parallel to the line section, which contains the interrupter interrupting the working circuit. This line piece can also be an adjustable electrical Resistance included, which is chosen so that it allows the control coils to work without Disturbance guaranteed, and which can be used to regulate the working current strength.

In the preferred implementation of the method according to the invention, the switch-off times of the working circuit to the .60 switch-on times are in a ratio of 1: 1 and have z. B. a duration of about ¹ J ₁ second each. | In order to achieve a uniform current consumption, the electroplating cells according to the invention are preferably switched in pairs and their working periods offset in time so that a cell is switched on when another cell fed by the same current source is switched off or short-circuited.

In the drawing is a circuit diagram for an example embodiment of the method reproduced according to the invention, namely two are fed from the same power source Cells shown, one of which is switched to the working position, the other on the other hand, is short-circuited when the working current is interrupted.

The power source 1 is formed by a battery, which of course by an equivalent DC power source, e.g. B. a dynamo, can be replaced. The supply of the working current to the cathode 2, 2 'or to the anode 3, 3' the associated cell takes place through lines 4 and 5 or 4 ', 5'. In line 5 or 5 ' is in front of the anode 3 or 3 'a switching tube 6 or 6' and a control resistor 7 or 7 ' switched on.

Parallel to the line piece containing the parts 6 and 7 or 6 'and 7' are two each Control coils 8, 9 or 8 ', 9'. The coils 8 and 8 'are assigned to the Schalttröhrcn 6 and 6' and manage their control. The coils 9 and 9 'effect the control accordingly of interrupters 10 or 10 ', which are arranged in a line 11 or 11', which cathode can connect to anode.

In the case of the cell 12 which is currently working according to the drawing, the switch 6 is closed, however, the short-circuit line 11 is interrupted by the switch 10. During the working period of cell 12 is the working current for the second cell 12 'through switch 6' interrupted, and at the same time their electrodes with the switch 10 'closed by the Short-circuit line 11 'connected to one another. Since in the previous working period of the cell 12 ', hydrogen is accumulated at the cathode and this is at a higher potential when the anode is charged, a polarization current now flows through the line 11 ', the equipotential bonding brings with it and makes the cell 12 'ready for the next working period, in which she swaps her role with cell 12.

The composition of the electrolyte can be any known composition and the usual surcharges to achieve the most dense and "pore-free" deposit possible own. For the same purpose, the electrolyte can be stirred in a known manner o, the like. Be set in motion, flowed through by purified air and heated to

To prevent the formation of hydrogen and the formation of a granular precipitate.

The duration of each working period and its relationship to the resting period of each bath can be based on Reason for experiments depending on the desired precipitation through appropriate adjustment the switching device can be adjusted.

In a practical implementation of the method according to the invention for silver plating

ίο of cutlery that have a silver plating of 100 g commercially available (i.e. 50 g each on a dozen spoons and forks of the cutlery) are provided, the production of this precipitate (at 2 V and 120 Amp.) takes 3 hours,

»5 while using the known method with constant, steady working current for the production of the same precipitate takes 6 hours, which is the advantage of the invention makes tangible. In addition, the precipitate obtained is more brilliant than that known method, so that, as already mentioned, the usual scratching is saved.

As switching devices, any known electrical or electromagnetic Apparatus are used which, after the desired period of time, automatically assigns the associated Insert or disengage switches when the current flows through them and which can be adjusted as required.

The commercially available mercury interrupter tubes provided for this purpose in the circuit shown 6, 10 and 6 ', 10' work in such a way that they switch on as soon as the associated control coil 8, 9 or 8 ', 9' is excited, and automatically when the coil is de-energized switch off. Because the two coils of one and the same cell have different dimensions as indicated in the drawing, a so-called flashing circuit is created, in which the excitation of one coil lags the other in phase, so that the One tube is switched on later than the other. By appropriate choice or adjustment of the coils is achieved in this way that just a tube switches on, when the other turns off.

Instead of this! commercially available switching devices of different types can be used for the same cell Design can be used, one of which with a current-carrying control coil or the like. switches on and switches off the other in the same state; their control coils are then also connected in parallel in the manner shown. Furthermore, with the appropriate circuit the polarization current can be used to control a switching device. Even Movements can be used to effect the rule

moderate current surges or switching operations.

Claims (7)

Patent claims: 1. A method for the galvanic production of metal ^{deposits, in which the working current is alternately switched off and on again 6} S, characterized in that in the interim times in which the working current is switched off, the potential formed by polarization by short-circuiting the anode and the cathode of the electroplating cell is brought to self-equalization. 2. The method according to claim i, characterized in that the short-circuiting in at regular intervals automatically, preferably by electrical or electromagnetic Switching devices (8, 9, 8 ', 9'), is effected. 3 / Method according to claim 1 and 2, characterized in that a switching device (9, 10 or 9 '10') the short-circuit connection (11, 11 ') at the same time establishes or interrupts, in which another the switching off or switching on of the working current causes. 4. The method according to claim 1 and 2, characterized in that one and the same Switching device switches the working current off or on and at the same time produces the short-circuit connection (11, 11 ') or interrupts. 5. Circuit for performing the method according to claim 2 to 4, characterized in that that the control coils (8, 9 or 8 ', 9') for the switching devices parallel to the one interrupting the working circuit Switches (6 or 6 ') of the switching device (6, 8 or 6', 8 ') are switched. 6. Further embodiment of the circuit according to claim 5, characterized in that that as switching devices. Mercury interrupter tubes (6, 10 or 6 ', 10') of the same design with control coils (8, 9 or 8 ', 9') of various types assigned in the flashing circuit Size to be used. 7. Another embodiment of the circuit according to claim 5, characterized in that that a switching device that the associated switch (6 or 6 ') when current is flowing Control coil (8 or 8 ') opens, ' and a switching device which closes the associated switch (10 or 10') when the control coil (9 or 9 ') is flowing through it (and vice versa). 1 sheet of drawings