EP0251272A1 - Electrodeposition device, particularly for aluminium - Google Patents

Abstract

An electroplating apparatus having electroplating tank which is closable air-tight and charged with an inert gas above the electrolyte and also includes one vacuum lock for charging and discharging goods to be electroplated. The lock chamber of the vacuum lock is equipped with an inner lock door and an outer lock door and is preferably evacuated with the assistance of a vacuum pump so that solvent vapors can be condensed during evacuation in a condenser. The apparatus increases the useful life of the electrolyte, particularly an aprotic, aluminum-organic electrolyte which is used in aluminum plating in comparison to previously known locks which use gas and liquid locks.

Description

The invention relates to a galvanizing device, in particular for the electrodeposition of aluminum from aprotic, oxygen-free and water-free aluminum-organic electrolytes
an airtight sealable electroplating trough that can be charged with an inert gas above the electrolyte,
- At least one lock for inserting and / or removing the goods to be electroplated and
- At least one of the lock chamber equipped with an inner lock door and an outer lock door and floodable with an inert gas.

Aluminum deposited from aprotic, oxygen and water-free organoaluminum electrolytes is characterized by its ductility, low pore density, corrosion resistance and anodizing ability. Since the entry of air through reaction with atmospheric oxygen and air humidity causes a considerable reduction in the conductivity and the service life of these electrolytes, the electroplating must be carried out in an air-tight treatment facility. So that the entry of air can also be prevented when loading and unloading the goods, charging and decharging locks are required, which are designed as gas locks, as liquid locks and as combined gas-liquid locks and are equipped with conveying means for the goods to pass through. DE-A-2 719 680 describes an electroplating device for the electroplating of aluminum from aprotic, Oxygen-free and water-free aluminum-organic electrolytes are known, in which a lock chamber floodable with inert gas and a prechamber floodable with inert gas are provided for introducing and removing the goods to be electroplated. The lock, designed as a gas lock, is equipped with a total of three lock doors due to the division into the actual lock chamber and an antechamber. So that no disruptive gases or air humidity can enter the inert atmosphere from outside, the actual lock chamber is preferably operated with excess pressure.

The lock design described above is not suitable for keeping air and moisture to a sufficient extent away from the electrolyte and thus precluding its slow destruction.

From EP-A-0 013 874 a device for the galvanic deposition of aluminum has become known, in which a lock system with a liquid lock is used for the introduction and removal of the goods to be galvanized. This liquid lock is preceded by a prechamber provided with an outer lock door and floodable with inert gas. With such a lock system, the penetration of atmospheric oxygen and humidity can be significantly reduced compared to pure gas locks.

In the above-described electroplating device, the goods to be electroplated are placed on goods racks with the help of an endless conveyor belt from the prechamber floodable with inert gas, through the liquid lock into the electroplating trough and, after electroplating, are removed in the opposite direction using the same conveyor belt. Doing it however, there is a considerable carryover of the electrolyte from the electroplating trough into the liquid lock. Due to the continuous contamination of the lock fluid with the electrolyte and the unavoidable reaction with traces of air and moisture in the prechamber flooded with inert gas, it cannot be prevented that reaction products settle on the cleaned goods during charging and prevent the subsequent separation of technically usable aluminum coatings.

In a device for the galvanic deposition of aluminum known from EP-B-0 053 676, contamination of the pretreated and to be galvanized goods in the liquid lock is prevented by a charging lock consisting of a prechamber, liquid lock and main chamber and a separate, Dechargierschleuse consisting of pre-chamber, liquid lock and main chamber are also arranged.

It has been found in practice that even with locks consisting of the prechamber, liquid lock and main chamber, certain amounts of atmospheric oxygen and air humidity are entrained, in particular with the goods, in the electrolytes and, in part, also get into the electroplating trough by continuously opening the lock doors. As a result, there is a certain reduction in the conductivity and the lifespan of the electrolyte.

The invention has for its object to provide a galvanizing device which is suitable for the electrodeposition of aluminum from aprotic, aluminum-organic electrolytes and ensures practically oxygen and water-free operation to further increase the life of the electrolyte.

This object is achieved in a generic electroplating device in that the lock is designed as a vacuum lock with an evacuable lock chamber.

The invention is based on the finding that small gas pressures can be generated in the lock chamber closed by the inner lock door and the outer lock door, which are substantially lower than the atmospheric pressure and in particular cause drying and degassing of the goods brought in. Water and oxygen are therefore not partially displaced by an inert gas or an inert liquid, as in the lock systems previously used, but actively removed by creating a vacuum, the amount of residual water and residual oxygen being reduced to extremely low values by selecting a correspondingly low gas pressure can. In addition to a considerable increase in the service life of the electrolyte used and the cost-effectiveness of galvanic metal deposition, a number of other advantages can also be achieved by using vacuum locks. In this way, essential steps of the pretreatment or post-treatment of the goods, such as dewatering, drying or rinsing, can be moved into the evacuable lock chamber of the vacuum lock. A single vacuum lock can then also be used as a charging and decharging lock, since the risk of contamination of the pretreated goods during charging can be excluded. Finally, it should also be emphasized that the hermetic sealing of the electrolyte releases harmful solvent vapors, such as e.g. B. toluene vapors to the environment can be completely excluded.

According to a preferred embodiment of the invention the vacuum lock is formed exclusively by the lock chamber that can be evacuated. The extremely high sealing effect of a vacuum lock means that there is no need for upstream or downstream lock chambers.

As already mentioned, the vacuum lock can also serve as a charging and decharging lock, whereby in contrast to the known liquid locks there is no risk of contamination of the goods to be brought in.

Compared to other methods of vacuum generation, it is particularly expedient if the lock chamber can be evacuated with the aid of a vacuum pump. A condensation device is then preferably arranged between the vacuum pump and the lock chamber. Solvent vapors drawn off from the lock chamber can then be condensed in this condensation device, collected in the liquid state and used again. It is particularly expedient if the condensate accumulating in the condensation device can be conveyed with the aid of a liquid pump into the electroplating trough or another bath container of the electroplating device that can be charged with inert gas.

According to a further particularly preferred embodiment of the invention, a spray device for spraying a rinsing liquid is arranged in the lock chamber. In this way, cleaning measures can be carried out both before and after the electroplating within the lock chamber. If the rinsing liquid is sprayed before the lock chamber is evacuated, the subsequent generation of the vacuum also simultaneously dries the goods.

Finally, it is particularly advantageous if the lock chamber can also be flooded with ambient air. In this case, the evacuated lock chamber is then flooded with ambient air before opening the outer lock door in order to reduce the inert gas consumption during decharging.

The invention also provides an expedient method for operating a galvanizing device equipped with a vacuum lock. It is provided that for charging the goods to be electroplated are first introduced into the lock chamber, that the outer lock door is then closed and a vacuum is created in the lock chamber and that after the vacuum has been created, the lock chamber is flooded with an inert gas, whereupon the inner one The lock door is opened and the goods to be electroplated are conveyed into the electroplating tank. By creating a vacuum and the subsequent flooding with an inert gas, the penetration of atmospheric oxygen and air humidity into the electroplating trough can be reduced to extremely small amounts that are absolutely harmless to the electrolyte.

After electroplating, the procedure is advantageously such that the finished galvanized goods are first introduced into the lock chamber for decharging, that the inner lock door is then closed and a vacuum is created in the lock chamber, and that after the vacuum has been created, the lock chamber is flooded with ambient air is what the outer lock door is opened and the goods are removed. In this way, the emission of harmful solvent vapors to the environment can be ruled out.

If the galvanized goods are sprayed with a rinsing liquid before the vacuum is generated, the cleaned goods are dried by the subsequent evacuation. Here, too, the release of vapors from the rinsing liquid to the environment can be ruled out.

When operating the electroplating device, it has proven to be particularly expedient if a vacuum is generated in the lock chamber with a gas pressure of between 1 and 10 -2 torr. In the mentioned range of gas pressure, on the one hand, a practically hermetic sealing of the electrolyte is effected, while, on the other hand, the structural effort for stiffening the lock chamber, which is stressed by atmospheric pressure, is still relatively low.

The galvanizing device according to the invention, equipped with at least one vacuum lock, was developed for use in the electrodeposition of aluminum from aprotic, oxygen-free and water-free organoaluminum electrolytes. However, an application is generally recommended in all cases in which electrodeposition of organophilic metals from non-aqueous electrolytes that are to be protected against the entry of air and moisture is carried out. The hermetic sealing of the electrolyte also results in greater flexibility than previously for the selection of the appropriate solvents. So toxic solvents such as e.g. B. benzene can be used.

An embodiment of the invention is shown in the drawing and will be described in more detail below.

• Fig. 1 in stark vereinfachter schematischer Darstellung das Funktionsprinzip einer mit einer Vakuum­schleuse ausgerüsteten Galvanisiereinrichtung und
• Fig. 2 eine Draufsicht auf die Vakuumschleuse der in Fig. 1 dargestellten Galvanisiereinrichtung.

Show it

• Fig. 1 in a highly simplified schematic representation of the principle of operation of a galvanizing device equipped with a vacuum lock and
• Fig. 2 is a plan view of the vacuum lock of the electroplating device shown in Fig. 1.

1 shows a highly simplified schematic representation of an electroplating trough Gw in which there is an aprotic, oxygen-free and water-free aluminum-organic electrolyte E. The electroplating trough Gw, which is hermetically sealed at the top by a hood H, is acted upon by an inert gas Ig above the electrolyte E, which is nitrogen, for example. An inert gas space designated as Ir is thus formed between the electrolyte mirror and the hood H. The hood H and the inert gas space Ir also extend over the lock chamber Sk of a vacuum lock Vs. As can also be seen from FIG. 2, the lock chamber Sk has a horizontal inner lock door Sti arranged within the inert gas chamber Ir and a vertical outer lock door Sta arranged below the inert gas chamber Ir. The open positions of the lock doors Sti and Sta are shown in dash-dot lines in FIGS. 1 and 2.

Below the hood H, horizontally oriented rails Ls extend in the inert gas space Ir, on which a transport carriage Tw provided with rollers Lr can be moved in the directions of the double arrow Dpf1. On the transport carriage Tw there is a hook Hk which is height-adjustable according to the double arrow Dpf2 and on which a goods rack Wg with the goods W to be aluminized is attached.

The lock chamber Sk can with the help of a vacuum pump Vp can be evacuated to a gas pressure of 10⁻¹ Torr, for example. There is a valve V1 in the suction line between the vacuum pump Vp and the lock chamber Sk, which valve is closed again after the lock chamber Sk has been evacuated. Solvent vapors, in particular toluene vapors, drawn off from the lock chamber Sk are condensed in a condensation device Ke arranged between the valve V1 and the vacuum pump Vp, the corresponding cooling system not being shown in more detail in the drawing. The condensate Ko is then conveyed into the electroplating tank Gw with the aid of a liquid pump Fp. The released from the solvent vapors and thus completely harmless gas from the lock chamber Sk is released to the environment, as indicated by the arrow Pf on the pressure side of the vacuum pump Vp.

The evacuated lock chamber Sk can be flooded either by opening a valve V2 with inert gas Ig or by opening a valve V3 with ambient air Ul. The valve V2 is connected to the inert gas supply line of the inert gas space Ir, whereby the connection to the inert gas space Ir after flooding has the same pressure on both sides of the inner lock door Sti and the inner lock door Sti can be opened easily.

Arranged in the lock chamber Sk is a spray device Se, which is only indicated schematically in FIG. 2 and via which a rinsing liquid Sf can be sprayed. The supply of the rinsing liquid Sf and its outflow can be shut off by valves V4 or V5.

The electroplating tank Gw contains equipment for electroplating which is not shown in the drawing the goods W. For example, according to EP-B-0 056 844, an annular design of the electroplating trough Gw with a rotatable contacting and holding device for the goods racks Wg is possible. According to EP-B-0 072 969, however, a plurality of individual cells and possibly also aprotic pretreatment and post-treatment baths can be arranged under the hood H. In this case, instead of two vacuum locks, only one vacuum lock can be used for charging and decharging. Instead of the goods W arranged in the goods racks Wg, the galvanizing device according to the invention can of course also be used to aluminize bulk goods, which are then introduced, for example in perforated drums, through the vacuum lock Vs into the electroplating trough Gw and removed in the opposite direction. Vibratory conveyors, spiral conveyors, conveyor belts and the like can also be used as a means of transport for pourable aluminum material.

• a. Öffnen der äußeren Schleusentür Sta.
• b. Einbringen der an einem Warengestell Wg befestigten Waren W in die Schleusenkammer Sk.
• c. Öffnen des Ventils V1 und Einschalten der Vakuumpumpe Vp.
• d. Nach dem Erreichen eines Vakuums von 10⁻¹ Torr Schließen des Ventils V1 und Ausschalten der Vakuum­pumpe Vp.
• e. Öffnen des Ventils V2 und Fluten der Schleusenkammer Sk mit Inertgas Ig.
• f. Öffnen der inneren Schleusentür Sti.
• g. Warengestell Wg an Haken Hk anhängen und mit Trans­portwagen Tw in Galvanisierwanne Gw einbringen.
• h. Aluminieren der Waren W.
• i. Warengestell Wg aus Galvanisierwanne Gw entnehmen und mit Transportwagen Tw in Schleusenkammer Sk einbrin­gen.
• j. Schließen der inneren Schleusentür Sti und des Ven­tils V2.
• k. Öffnen des Ventils V1 und Einschalten der Vakuum­pumpe Vp.
• 1. Nach dem Erreichen eines Vakuums von 10⁻¹ Torr Schließen des Ventils V1 und Ausschalten der Vakuum­pumpe Vp.
• m. Öffnen des Ventils V3 und Fluten der Schleusenkammer Sk mit Umgebungsluft Ul.
• n. Öffnen der äußeren Schleusentür Sta.
• o. Entnehmen des Warengestells Wg mit den aluminierten Waren W.

A preferred mode of operation of the electroplating device explained above with reference to FIGS. 1 and 2 comprises the following steps:

• a. Opening the outer lock door Sta.
• b. Introducing the goods W attached to a goods rack Wg into the lock chamber Sk.
• c. Open valve V1 and switch on vacuum pump Vp.
• d. After reaching a vacuum of 10⁻¹ Torr closing valve V1 and switching off the vacuum pump Vp.
• e. Open valve V2 and flood the lock chamber Sk with inert gas Ig.
• f. Opening the inner lock door Sti.
• G. Attach the goods rack Wg to the hook Hk and bring it into the galvanizing trough Gw with the Tw trolley.
• H. Aluminizing goods W.
• i. Remove the goods rack Wg from the electroplating trough Gw and insert it into the lock chamber Sk with the Tw trolley.
• j. Closing the inner lock door Sti and the valve V2.
• k. Open valve V1 and switch on vacuum pump Vp.
• 1. After reaching a vacuum of 10⁻¹ Torr, close the valve V1 and switch off the vacuum pump Vp.
• m. Opening valve V3 and flooding the lock chamber Sk with ambient air Ul.
• n. Opening the outer lock door Sta.
• o. Removing the goods rack Wg with the aluminized goods W.

In the procedure described above, the spray device Se can also be used for the pretreatment or aftertreatment, as required. The rinsing liquid Sf used here is preferably the toluene already present in the electrolyte E.

Claims (12)

1. Electroplating device, in particular for the electrodeposition of aluminum from aprotic, oxygen-free and water-free aluminum-organic electrolytes (E), with
an airtight sealable electroplating trough (Gw) above the electrolyte (E) with an inert gas (Ig),
- At least one lock for introducing and / or discharging the goods to be electroplated (W) and
- at least one lock chamber (Sk) equipped with an inner lock door (Sti) and an outer lock door (Sta) and floodable with an inert gas (Ig),
characterized in that the lock is designed as a vacuum lock (Vs) with an evacuable lock chamber (Sk). 2. Electroplating device according to claim 1, characterized in that the vacuum lock (Vs) is formed exclusively by the evacuable lock chamber (Sk). 3. Electroplating device according to claim 1 or 2, characterized in that the vacuum lock (Vs) serves as a charging and decharging lock. 4. Electroplating device according to one of the preceding claims, characterized in that the lock chamber (Sk) can be evacuated with the aid of a vacuum pump (Vp). 5. Electroplating device according to claim 4, characterized in that between the Vacuum pump (Vp) and the lock chamber (Sk) a condensation device (Ke) is arranged. 6. Electroplating device according to claim 5, characterized in that in the condensation device (Ke) accumulating condensate (Ko) with the aid of a liquid pump (Fp) in the electroplating tank (Gw) or another inert gas (Ig) bath container of the electroplating device can be conveyed . 7. Electroplating device according to one of the preceding claims, characterized in that a spray device (Se) for spraying a rinsing liquid (Sf) is arranged in the lock chamber (Sk). 8. Electroplating device according to one of the preceding claims, characterized in that the lock chamber (Sk) can also be flooded with ambient air (Ul). 9. A method of operating a galvanizing device according to one of claims 1 to 8, characterized in that for charging the goods to be galvanized (W) are first introduced into the lock chamber (Sk), that then the outer lock door (Sta) is closed and in the Lock chamber (Sk) a vacuum is created and that after the vacuum has been created the lock chamber (Sk) is flooded with an inert gas (Ig), whereupon the inner lock door (Sti) is opened and the goods to be electroplated (W) into the electroplating tank ( Gw) are promoted. 10. A method according to claim 9, characterized labeled in records that for the decharging the finished galvanized goods (W) are first introduced into the lock chamber (Sk), that then the inner lock door (Sti) is closed and a vacuum is created in the lock chamber (Sk) and that after the vacuum has been created, the Flood chamber (Sk) is flooded with ambient air (Ul), whereupon the outer lock door (Sta) is opened and the goods (W) are removed. 11. The method according to claim 10, characterized in that the galvanized goods (W) in the lock chamber (Sk) are sprayed with a rinsing liquid (Sf) before generating the vacuum. 12. The method according to any one of claims 9 to 11, characterized in that a vacuum is generated in the lock chamber (Sk) with a gas pressure between 1 and 10⁻² Torr.

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