DE102010044551A1 - Anode and their use in an alkaline electroplating bath - Google Patents

Abstract

The invention relates to an anode and its use in an alkaline electroplating bath. In electroplating, this anode is suitable for use in strongly alkaline, galvanic electrolytes based on sodium hydroxide or potassium hydroxide for the deposition of zinc and zinc alloys on substrates of steel and zinc die-cast.

Description

The invention relates to an anode and its use in an alkaline electroplating bath. This anode is suitable in electroplating applications for use in strongly alkaline, galvanic electrolytes based on sodium hydroxide or potassium hydroxide for the deposition of zinc and zinc alloys on substrates of steel and zinc die-casting.

According to the state of the art, similar membrane anodes are used in the field of cataphoretic dip coating in order to transfer interfering anions, which are formed during the electrophoretic painting process in the water-based paint bath, via special anion exchange membranes into a dilute acid anolyte and thus to remove it from the paint bath.

• – Art der Membran
• – Querschnitte der stromleitenden Teile
• – chemische Beständigkeit der Materialien

den Anforderungen deutlich höherer angewendeter Stromstärken und kleinerer Spannungen, starke Alkalität der galvanischen Elektrolyte und der Anolyte angepasst sein.The principle of operation of the anion exchange membrane when used in electroplating for metal deposition is analogous, but features such as:

• - Type of membrane
• - Cross sections of the current-conducting parts
• - chemical resistance of the materials

be adapted to the requirements of significantly higher applied currents and lower voltages, strong alkalinity of the galvanic electrolytes and anolyte.

The state of the art continues to be the most common use of anodes made of steel, stainless steel or nickel-plated steel in alkaline galvanizing electrolytes. In this case, different geometric shapes are chosen, for. As plates in rectangular shape, expanded metal in a rectangular or cylindrical shape, rods, tubes and others.

Strongly alkaline galvanic electrolytic electrolytes tend, depending on the electrolyte composition, after a relatively short operating time of a few weeks to partially strong deposits on the anode surfaces. This has the disadvantage of the gradual deterioration of the cathodic current efficiency and thus the efficiency of the galvanic process and the galvanic plant. The cost of electrical energy per coated surface area increases.

These deposits are large proportions of sodium carbonate and sodium oxalate due to oxidation at the anode surface in sodium hydroxide based electrolytes. In addition, organic degradation products alter the initial properties of the galvanic electrolytes.

A regular, sometimes high cleaning effort on the anodes and the containers is necessary. The carbonate content of such electrolytes often has to be lowered with crystallizers with additional electric energy consumption. Alternatively, the galvanic baths are recalculated. The spent electrolytes are disposed of and generate additional chemicals, disposal and wastewater treatment costs, as well as equipment downtime.

• – platiniertes Titan als Anodenwerkstoff
• – perfluorierte Kationenaustauscher-Membran sehr kostenintensiv in der Beschaffung und werden deshalb auch ausschließlich für alkalische Zink-Nickel-Elektrolyte verwendet. Der Zink-Nickel-Elektrolyt (Katholyt) wird hierbei durch eine Kationenaustauscher-Membran von der Anode getrennt. Als Anolyt wird verdünnte Schwefelsäure verwendet.

The in the EP 1 344 850 A1 described anodes are due to the used, high quality materials

• - Platinized titanium as the anode material
• - Perfluorinated cation exchange membrane very costly in the procurement and are therefore used exclusively for alkaline zinc-nickel electrolytes. The zinc-nickel electrolyte (catholyte) is separated from the anode by a cation exchange membrane. The anolyte used is dilute sulfuric acid.

• a. Verdünnung des Zink-Nickel-Elektrolyten während des galvanischen Prozesses infolge Neutralisation des Natriumhydroxides durch Protonen des Schwefelsäure-Anolyten, die über die Kationenaustauscher-Membran „transportiert” werden und mit Hydroxidionen zu Wasser reagieren: H⁺ _Anolyt + OH^– _Katholyt → H₂O_Katholyt Dieser Prozess läuft in einer Richtung ab und führt zu permanenter Verdünnung des Zink-Nickel-Elektrolyten.
• b. Volumenanstieg des Zink-Nickel-Elektrolyten: Die in Punkt a) beschriebene Verdünnung und die daraus resultierende, notwendige Zugabe von Natriumhydroxid zur Wiederherstellung der für die Legierungsabscheidung erforderlichen Natriumhydroxidkonzentration im Zink-Nickel-Elektrolyten führt zu einem kontinuierlichen Volumenanstieg des Elektrolyten. Durch Wassertransport vom Schwefelsäure-Anolyten über die Kationenaustauschmembran in den Katholyten (Zink-Nickel-Elektrolyten) infolge osmotischer Druckunterschiede wird dieser Effekt verstärkt.
• c. Aus a) und b) folgend wird ein zusätzlicher, erheblicher technischer und energetischer Aufwand betrieben, um den permanent entstehenden, schwach verdünnten Elektrolyt-Volumenüberhang mittels Vakuumverdampfer aufzukonzentrieren und diskontinuierlich wieder in den Prozess zurückzuführen.

As disadvantages of the large-scale application of EP 1 344 850 A1 can be named:

• a. Dilution of the zinc-nickel electrolyte during the galvanic process due to neutralization of the sodium hydroxide by protons of the sulfuric acid anolyte, which are "transported" through the cation exchange membrane and react with hydroxide ions to form water: H ⁺ _anolyte + OH ^- _catholyte → H ₂ O _catholyte This process is unidirectional and leads to permanent dilution of the zinc-nickel electrolyte.
• b. Volume increase of the zinc-nickel electrolyte: The dilution described in point a) and the resulting necessary addition of sodium hydroxide to restore the sodium hydroxide concentration in the zinc-nickel electrolyte required for the alloy deposition leads to a continuous increase in the volume of the electrolyte. Water transport from the sulfuric acid anolyte via the cation exchange membrane into the catholyte (zinc-nickel electrolyte) due to osmotic pressure differences enhances this effect.
• c. From a) and b) following, an additional, considerable technical and energetic effort is operated to concentrate the permanently formed, weakly diluted electrolyte volume excess by means of a vacuum evaporator and discontinuously fed back into the process.

Proceeding from this, it is the object of the invention to provide a low-cost anode which minimizes the formation of decomposition products in strongly alkaline electrolytes, regenerates used zinc electrolytes operated with conventional anodes and makes them more efficient, and keeps new electrolytes at a constantly high level of performance.

This object is achieved by the anode with the features of claim 1. Claim 11 relates to an alkaline electroplating bath and claim 15 relates to the use of the anode. Further advantageous embodiments are contained in the dependent claims.

According to the invention, an anode with an ion exchange membrane for an alkaline electroplating bath for depositing zinc and / or zinc alloys is proposed, wherein the anode is at least partially surrounded by the ion exchange membrane, by which the anode is separable from an alkaline electrolyte and the cathode. The anode according to the invention is characterized in that the ion exchange membrane is an anion exchange membrane.

An anion exchange membrane separates the galvanic zinc electrolyte from the anode to prevent undesired side reactions such as oxidation of the organic additives with formation of deposits on the anode surfaces.

Aged electrolytes containing decomposition products can be regenerated when using the anode according to the invention and thus become more efficient again. Consequently, in this way, the life can be extended before a new galvanic bath is to be set.

In this case, the anion exchange membrane preferably consists of polyetheretherketone or contains this.

Polyetheretherketone belongs to the group of polyetherketones. These are characterized by the fact that they are high temperature resistant thermoplastics. The most important member of this group is the polyetheretherketone, whose melting point is 335 ° C. Polyether ketones are resistant to almost all organic and inorganic chemicals. Furthermore, they are resistant to hydrolysis up to about 280 ° C.

Preferably, the anion exchange membrane of the anode according to the invention has a thickness of 0.1 mm to 0.13 mm.

Furthermore, the anion exchange membrane preferably has a specific resistance of <1 Ω / cm.

Another variant of the anion exchange membrane is a multilayer structure.

The anode can be made of steel, stainless steel, nickel and / or nickel-plated steel or contain this. Furthermore, an expanded metal of the aforementioned materials in cylindrical form with screw and fastening device can be used on an anode rail.

The anode may be rectangular, round, cylindrical or tubular. Furthermore, the anode may be surrounded by plastic, in particular in the form of a plastic fabric, plastic walls or a plastic floor. Moreover, the anode can be rigid or flexible.

For example, a round anode cylinder jacket of an inner support grid tube, an anion exchange membrane and a protective sock, the z. B. plastic fabric or a Plastic mesh is to be surrounded. In this case, the protective sock, the anion exchange membrane and the inner support grid tube are preferably connected to one another in a layered manner.

In a box-shaped, preferred embodiment variant, the anolyte inlet and the anolyte outlet are arranged perpendicular to one another, the anolyte inlet being arranged on the upper side of the anode box and the anolyte outlet being arranged on the rear side of the anode box. In this case, the anode may be made of plug metal.

According to a further variant, it is preferred that the anode is constructed angled. In the case of a tubular, angled variant, the anode may be designed, for example, as a spiral, which may be flexible.

Furthermore, each anode used in a galvanic electrolyte preferably has in each case one anolyte feed and one anolyte return, so that all the anodes have the same functional and reaction conditions.

In the application of zinc-nickel alloy electrolytes, the use of special anodes based on the EP 1 344 850 A1 proven because it is the formation of degradation products by anodic oxidation in direct contact of the electrolytes, consisting of sodium hydroxide, nickel sulfate solution, amines as complexing agent and other organic compounds is greatly reduced and the cathodic current efficiency of the galvanic process of 30-50% without application of Anodes can be increased to 60-90%, depending on the electrolyte composition and applied current.

Unlike when using cation exchange membrane anodes, as in US Pat EP 1 344 850 A1 described using the anode according to the invention, the use of invest- and cost-intensive, technical peripherals such. B. vacuum evaporator for the constriction of catholyte volume excess pointless because the effects described on page 3, line 25 to page 4, line 14 does not occur.

According to the invention, an alkaline electroplating bath is provided for depositing zinc and / or zinc alloy with an anode and a cathode, wherein the anode is separated from an alkaline electrolyte by an ion exchange membrane. According to the invention, the ion exchange membrane is an anion exchange membrane.

The electroplating bath preferably contains an alkaline solution as anolyte. This has the advantage that, in the case of membrane defects, no acid neutralizes the alkaline zinc or zinc alloy electrolyte and, in extreme cases, renders it unusable.

As the membrane, an alkali-resistant anion exchange membrane is preferably used for this invention.

Preferably, the alkaline solution in the electroplating bath is a sodium hydroxide solution and / or a potassium hydroxide solution.

It is preferred that the alkaline solution has a pH in the range of 10 to> 14.

If in the anode of the invention, the anion exchange membrane replaced by a cation exchange membrane and sulfuric acid used as the anolyte, the regeneration function for previously conventionally used zinc-nickel electrolytes can not be met, as by the contact of protons from the anolyte (sulfuric acid) with cyanide ions the catholyte (zinc-nickel electrolyte) on the membrane cathode side the risk of the formation of highly toxic hydrogen cyanide is given.

The use of the described anode in a galvanic bath is also according to the invention.

The amount of negative charge consumed in the electrodeposition at the cathode corresponds to the equivalent amount of positive charge consumed in the form of simply positively charged hydroxide ions at the anode, thereby forming water and oxygen.

Anode:

• 4OH ^- - 4e → 2H ₂ O + O ₂ (I)

Cathode:

• Zn ²⁺ + 2e → 2Zn (metal deposition) (II) 2H ⁺ + 2e → H ₂ (hydrogen separation) (III)

The reaction (III) as co-reaction to the metal deposition (II) is greatly slowed down when using membrane anodes.

It follows that a uniform consumption of hydroxide ions takes place in the zinc or zinc alloy electrolyte and in the anolyte, which is accompanied by volume reduction. The volume reduction is partially compensated in the galvanic practice by the necessary supplemental chemicals and depending on volume carryover with the galvanized goods and their goods carriers is additionally filled with water if required.

Thus, no continuous increase in volume in the galvanic electrolyte due to dilution effects is produced.

Osmosis effects from dehydration from the anolyte during plant downtime are prevented by adjusting the anolyte to a higher sodium hydroxide concentration than the catholyte (zinc electrolyte).

From the laboratory and pilot experiments, a sodium hydroxide concentration of 150-160 g / l in the anolyte was found to be favorable at a sodium hydroxide content of 120 g / l in the zinc electrolyte.

At too high a concentration of sodium hydroxide in the anolyte in the de-energized state osmosis takes place in the opposite direction, d. H. Dilution of the anolyte by water from the catholyte with volume increase of the anolyte to balance the ionic activities of anolyte and catholyte.

This condition is uncritical, since the volume increase in the anolyte can be traced back to the catholyte (in practice, however, the anolyte can "overflow" from the membrane anodes).

The volume balance of anolyte and catholyte remains balanced.

The use of membrane anodes with anion exchange membrane in used zinc-nickel electrolytes enables regeneration thereof by cyanide ions formed by conventional zinc-nickel baths (without membrane technology) by chemical reaction at the anode and lowering the cathodic current efficiency , due to their negative electrical charge in the anolyte and can be disposed of with this targeted.

Furthermore, although to a lesser extent, carbonate and sulfate ions, which also slow the electrodeposition process, are transferred from the zinc or zinc alloy electrolyte via the anion exchange membrane to the anolyte and can be systematically removed.

Based on the following 1 to 5 as well as with reference to Example 1, the application according to the object will be explained in more detail, without limiting this to these variants.

1 shows an anode structure with a cylindrical shape.

2 shows an anode structure with a membrane body in box form.

3 shows an anode structure with angled tubular shape.

4 shows several anodes in a galvanic bath.

5 shows the schematic structure of a galvanic bath.

1a shows an embodiment of the anode 1 in a schematic representation. This has a cylindrical shape. At the top is the Anolytezulauf 2 centered and the Anolytrücklauf 4 the caustic soda as anolyte 3 shown on the side. This embodiment has a screw cap 5 on. The anode 1 is from an inner support grid pipe 8th and the anion exchange membrane 7 surround. As materials for the anion exchange membrane 7 are, for example fumasep ^® FAB or fumasep ^® FAA Fa. Fumatech used. The protective stocking 6 made of plastic fabric can be made for example of polypropylene. Furthermore, an outer protective grid pipe may optionally be present. The anode 1 as tubular anode can optionally made of steel, stainless steel, nickel or expanded metal from the aforementioned material in cylindrical form with screw cap 5 and fastening device on the anode rail. The anolyte return 4 ensures degassing of the anolyte 3 of oxygen, which in the galvanic process at the anode 1 is formed. As anolyte 3 For example, caustic soda is used (150 to 180 g / l sodium hydroxide). At the anode attachment 9 In addition, the power supply takes place. Furthermore, below the anode 1 the river of the anolyte 19 shown.

In 1b is a side view of an anode 1 with screw cap 5 shown. On the screw cap 5 is the anode attachment 9 arranged. Furthermore, the Anolytzulauf 2 as well as the anolyte return 4 shown.

1c shows a rotated by 90 ° representation of 1b constructed from an anode 1 with screw cap 5 and arranged thereon anode attachment 9 , Furthermore, the Anolytzulauf 2 as well as the anolyte return 4 displayed.

In 2 is a box-shaped variant of the anode according to the invention 1 shown. The anode 1 here has a rectangular shape. It is from the anode box 11 surround. By the Anolytezulauf 2 as well as the Anolytablauf 4 ' becomes the liquid level of the anolyte 10 in the anode box 11 regulated. The anolyte feed 2 is located at the top of the body. The anolyte outlet 4 ' is at the back of the anode box 11 localized. The anode 1 can be made of expanded metal.

In 3 is an angled pipe shape made of plastic. The anode 1 consists in this embodiment of flexible anode material, such as stainless steel, and is designed as a spiral. In this embodiment, the anode 1 a tubular, angled sheath 20 on.

In 4 is a galvanic bath with galvanizing drum 21 and anode rails 23 for fastening and power transmission of the anodes 1 for operating multiple anodes 1 shown. The anolyte circuit passes through a circulation pump 13 , a filter 14 and one flowmeter each 15 per anode. Each membrane anode is via inlet outlets 24 and return pipes 25 involved in the anolyte circuit. This ensures that all anodes 1 can obtain the same reaction conditions. Furthermore, the structure has an anolyte reservoir 12 on. By this construction, it is possible to carry out at any time corrections of the sodium hydroxide content, sodium carbonate content and the anolyte volume. Furthermore, via the anion exchange membrane 7 separated, the galvanic process inhibiting anions, such as cyanide, carbonate or sulfate are removed.

5 shows a variant of the electroplating bath. The anodes 1 are from the anolyte 3 surrounded and by the zinc-nickel electrolyte 18 by a respective anion exchange membrane 7 separated. The anodes 1 as well as the cathode 17 are in an electrolyte container 16 , As anolyte 3 Caustic soda surrounds the anodes 1 ,

Example 1:

Technical requirements:

• Experimental arrangement: see 5

Laboratory membrane Anode: ∅ V2A tube anode: 1/2 '' (2.07 cm) Effective length of tubular steel anode: 12 cm Geometric surface steel tube anode: 0.8 dm ² Anolyte cell with anion exchange membrane: ∅ Membrane tube: 65 mm Length of membrane tube: 11 cm Surface membrane tube: 2.5 dm ² Volume membrane tube: Max. 330 ml Volume membrane tube effective: 250 ml Number of anolyte cells: 2 pieces Anolyte: caustic soda NaOH 1 day 120 g / l 2 day 150 g / l 3rd day 180 g / l Cathode: steel sheet 21 × 15 cm Geometric area: 2 pages 6.4 dm ² Zinc-nickel electrolyte: Performa 285 Status: second hand Colour: brown Electrolyte container: plastic Volume: 10 liters Electrolyte composition: Zn 6.8 g / l Ni 0.83 g / l NaOH 120.0 g / l Na ₂ CO ₃ 89.0 g / l Na ₂ SO ₄ 12.7 g / l cyanide 24 mg / l Galvanisierdaten: Current: 13A Cathodic current density: ~ 2 A / dm ² Anodic current density: ~ 8 A / dm ² Exposure time per plating cycle: 2 h

Experimental procedure:

• a) The zinc-nickel electrolyte was loaded with 30 Ah / l, i. H. three days approx. 8 hours each with the described current load.
• b) The chemical composition with regard to sodium hydroxide (NaOH), nickel (Ni), zinc (Zn) was regularly checked analytically and kept constant by adding nickel solution, sodium hydroxide and dissolving zinc metal.
• c) The cathode sheets were removed in the cycle of one hour and measured the layer thickness of the zinc-nickel layer.

Test results:

• a) At the beginning of the experiments, an average deposited layer thickness of 9 μm was measured on the cathode plate. This corresponds to a cathodic current efficiency of approx. 30%.
• b) After a current load of the electrolyte of about 20 Ah / l, a color change from brown to burgundy was observed. This indicated qualitatively that the plating process did not lead to any new decomposition products due to anodic oxidation. For comparison, a newly prepared zinc-nickel electrolyte is of violet color and shows a burgundy color after a low current load.
• c) With the color change, a significant increase in the cathodic current efficiency was measured: After a coating time of one hour, an average layer thickness of 15 μm was measured. This corresponds to a cathodic current efficiency of about 50%.
• d) After the daily downtime without current load (about 12-14 hours) with the fate of anolyte filled membrane tubes in the zinc-nickel bath was found after the first day that the anolyte volume in both membrane tubes had fallen by about 25%, and below the zinc-nickel electrolyte level. The sodium hydroxide concentration of the remaining anolyte had increased to 150 g / l. The cause can be explained by osmotic pressure differences between anolyte and catholyte (zinc-nickel electrolyte).
• e) Increasing the sodium hydroxide concentration to 150 g / l and filling the anolyte volume in the membrane tubes with demineralized water resulted in no dehydration in the anolyte after the second day.
• f) Increasing the sodium hydroxide concentration to 180 g / L in the anolyte on the third day after the downtime showed an increase in the volume of the anolyte in the membrane tubes above the electrolyte level of the zinc-nickel bath until overflowing. By dehydration (osmosis) from the zinc-nickel electrolyte, a sodium hydroxide concentration of 155 g / l had set in the anolyte.
• g) After a current load of the zinc-nickel electrolyte of 30 Ah / l (third day), a further increase in performance of the zinc-nickel electrolyte could be detected: The average measured layer thickness after one hour of coating time was now 19 microns. This corresponds to a cathodic current efficiency of approx. 60%.
• h) The following analysis values were determined after 30 Ah / l current load (loss due to overflowing anolyte due to osmosis not taken into account):

Zinc-nickel electrolyte: Zn 6.5 g / l Ni 0.9 g / l NaOH 125.0 g / l Na ₂ CO ₃ 86.0 g / l Na ₂ SO ₄ 12.0 g / l cyanide 11 mg / l anolyte: Zn 0.1 g / l Ni 10 mg / l NaOH 155.0 g / l Na ₂ CO ₃ 5 g / l Na ₂ SO ₄ 4 g / l cyanide 5 mg / l

Data analysis:

• a) The experiments showed a significant decrease in the cyanide concentration in the zinc-nickel electrolyte due to removal via the anion exchange membrane, wherein the absolute amount of cyanide in the anolyte was not found again. This may be due to oxidative decomposition of cyanide in the anolyte.
• b) Since the formation of cyanide by the anion exchange membrane was prevented, the concentration of cyanide in the zinc-nickel electrolyte continuously decreased.
• c) As a result of decreasing cyanide concentration, a color change of the zinc-nickel electrolyte and a clearly measurable increase in the cathodic current yield took place.
• d) Carbonate and sulfate ions have been slightly removed from the zinc-nickel electrolyte. This also contributes to the increase in the cathodic current efficiency.
• e) In order to avoid precipitation and deposits of calcium or magnesium carbonate and sulfate, since these salts can severely impair membrane function or lead to total failure, the anolyte must always be prepared and supplemented with demineralized water.

The test of an in 1a The anode shown in the pilot test has confirmed the operation according to the laboratory tests described.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1344850 A1 [0008, 0009, 0026, 0027]

Claims (15)

An anode with an ion exchange membrane for an alkaline galvanic bath for the deposition of zinc and / or zinc alloys, wherein the anode is at least partially surrounded by the ion exchange membrane, by which the anode of an alkaline electrolyte and the cathode is separable, characterized in that the ion exchange membrane is an anion exchange membrane , Anode according to the preceding claim, characterized in that the anion exchange membrane consists of or contains polyetheretherketone. Anode according to one of the preceding claims, characterized in that the anion exchange membrane has a thickness of 0.1 mm to 0.13 mm. Anode according to one of the preceding claims, characterized in that the anion exchange membrane has a specific resistance of <1 Ω / cm. Anode according to one of the preceding claims, characterized in that the anion exchange membrane has a multilayer structure. Anode according to one of the preceding claims, characterized in that the anode consists of or contains steel, stainless steel, nickel and / or nickel-plated steel. Anode according to one of the preceding claims, characterized in that the anode is rectangular, round, cylindrical or tubular. Anode according to one of the preceding claims, characterized in that the anode is rigid or flexible. Anode according to one of the preceding claims, characterized in that the anode of plastic, in particular in the form of a plastic fabric and / or plastic mesh, plastic walls and a plastic bottom, is surrounded. Anode according to one of the preceding claims, characterized in that the anode is constructed at an angle. An alkaline plating bath for depositing zinc and / or zinc alloys with an anode and a cathode, the anode being separated from an alkaline electrolyte by an ion exchange membrane, characterized in that the ion exchange membrane is an anion exchange membrane. Electroplating bath according to the preceding claim, characterized in that it contains an alkaline solution as anolyte. Electroplating bath according to the preceding claim, characterized in that the alkaline solution is a sodium hydroxide solution and / or a potassium hydroxide solution. Electroplating bath according to one of claims 13 to 15, characterized in that the alkaline solution has a pH in the range from 10 to> 14. Use of the anode according to one of claims 1 to 10 in a galvanic bath according to one of claims 11 to 14.

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