CN105441995A - Glucosaminic-acid cyanide-free gold-plating electroplating liquid and electroplating method thereof - Google Patents
Glucosaminic-acid cyanide-free gold-plating electroplating liquid and electroplating method thereof Download PDFInfo
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- CN105441995A CN105441995A CN201410468824.1A CN201410468824A CN105441995A CN 105441995 A CN105441995 A CN 105441995A CN 201410468824 A CN201410468824 A CN 201410468824A CN 105441995 A CN105441995 A CN 105441995A
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- gold
- electroplate liquid
- plating
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- electroplating
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Abstract
The invention discloses a glucosaminic-acid cyanide-free gold-plating electroplating liquid and an electroplating method thereof. The electroplating liquid comprises 10-15 g/L of gold trichloride calculated based on gold, 80-104 g/L of a glucosaminate, 32-60 g/L of iminodiacetic acid and 1-5 g/L of glycine. The glucosaminate is taken as a coordinating agent, iminodiacetic acid is taken as an auxiliary coordinating agent, and the glucosaminate and iminodiacetic acid give play to synergic effect for improving the gold coordinating capability. Glycine is taken as a stabilizing agent and prevents the electroplating liquid from being oxidized under an acidic condition. Gold trichloride is taken as a gold main salt, and thus the obtained electroplating liquid possesses relatively good dispersing force and covering power, and is high in cathode current efficiency and excellent in performances. A plating layer obtained by employing the electroplating liquid for performing electroplating under an alkaline condition is low in porosity, high in brightness and good in plating-layer quality.
Description
Technical field
The present invention relates to electro-coppering tin technical field, particularly relate to a kind of electroplate liquid and electro-plating method thereof of glucosaminicacid cyanogen-less gold.
Background technology
Gold ductility is good, is easy to polishing, has lower contact resistance, and conductivity, welding property are good, are widely used in the electronics industry as solderable coating.Gold is high temperature resistant, and hard gold is also more wear-resisting, and therefore gold plate is widely used in the part that precision instrument, instrument, printed-wiring board (PWB), unicircuit, shell, electric contact etc. require electrical parameter performance long-term stability.The chemical stability of gold is very high, and be only dissolved in chloroazotic acid and be insoluble to other acid, thus gold plate solidity to corrosion is very strong, and have good discoloration-resisting, meanwhile, au-alloy coating has multiple color tones, therefore is commonly used for famous and precious decorative coating, as jewelry, wrist-watch, artwork etc.
Gold-plated and the cyanogen-less gold of cyanogen is had according to whether being divided into containing prussiate in gold-plated plating solution.Because prussiate has severe toxicity, under the large historical background progressively strengthened of environmental consciousness, cyanide electroplating gold starts to be limited by legislation by national governments.The exploitation of cyanogen-less gold highlights huge market outlook.The performance of existing cyanide electroplating gold ubiquity plating solution is not good, and the technological deficiency that quality of coating is not high, these seriously constrain cyanide-free gold electroplating further genralrlization industrially.
Summary of the invention
In view of this, one aspect of the present invention provides a kind of electroplate liquid of glucosaminicacid cyanogen-less gold, and the plating solution performance of this electroplate liquid is better, and the quality of coating using this plating solution to obtain is higher.
An electroplate liquid for glucosaminicacid cyanogen-less gold, is characterized in that, comprises in gold 10 ~ 15g/L gold perchloride, in glucosamine acid group 80 ~ 104g/L glucosamine hydrochlorate, 32 ~ 60g/L iminodiethanoic acid and 1 ~ 5g/L glycine.
Wherein, 12g/L gold perchloride is comprised further, in glucosamine acid group 90g/L glucosamine hydrochlorate, 45g/L iminodiethanoic acid and 3g/L glycine.
Wherein, described glucosamine salt is one in glucosamine saccharic acid potassium, glucosamine Calciofon and glucosamine saccharic acid zinc or at least two kinds.
In the technical scheme of above electroplate liquid, select as gold perchloride is main salt.In the present invention, gold ion content can make that cathode current density is higher and sedimentation velocity is very fast.If golden salts contg is too high, not only can increase electroplating cost, and coating can be made to produce the phenomenon of fragility increase; If content is too low, tint is poor, and cathode current density is lower, and sedimentation velocity is slower.
Glucosaminicacid and salt thereof is selected to be main coordination agent.The amino contained in glucosamine acid molecule, five hydroxyls and a carboxyl, make it become the good part of gold ion.Select iminodiethanoic acid for helping coordination agent, iminodiethanoic acid and glucosaminicacid act synergistically, and can further improve the coordination ability with gold ion, improve the stability of deposition of gold in plating solution, thus improve the planarization etc. of coating.
Take glycine as stablizer, the phenomenon that the plating solution that acidic conditions can be avoided to cause easily is oxidized.
Except mentioned component, the present invention also can select suitable amounts other in this area the additive commonly used, such as conductive agent salt of wormwood, pH buffer reagent, brightening agent etc., these all can not damage the characteristic of coating.
The present invention provides a kind of electro-plating method of electroplate liquid of glucosaminicacid cyanogen-less gold on the other hand, and the better performances of the electroplate liquid that the method adopts is higher according to quality of coating prepared by the method.
Use an above-mentioned electroplate liquid electric plating method, comprise the following steps:
(1) electroplate liquid is prepared: in water, dissolve each feed composition form electroplate liquid, described often liter of electroplate liquid contains in gold 10 ~ 15g gold perchloride, in glucosamine acid group 80 ~ 104g glucosamine hydrochlorate, 32 ~ 60g iminodiethanoic acid and 1 ~ 5g glycine;
(2) insert with pretreated negative electrode and anode and pass into electric current in described electroplate liquid and electroplate.
Wherein, described electric current is monopulse rectangular wave current; The pulsewidth of described monopulse rectangular wave current is 0.5 ~ 1ms, and dutycycle is 5 ~ 30%, and average current density is 0.5 ~ 1A/dm
2.
Wherein, in described step (2), the pH of electroplate liquid is 4 ~ 6.
Wherein, the temperature of electroplate liquid is 50 ~ 60 DEG C.
Wherein, the time of plating is 20 ~ 40min.
Wherein, the area ratio of described step (2) Anodic and negative electrode is (1 ~ 4): 1.
In the technical scheme of above electro-plating method, monopulse rectangular wave current is defined as at t
1passing into current density in time is J
pelectric current, at t
2without passing into electric current in time, it is a kind of intermittent pulse current.Dutycycle is defined as t
1/ (t
1+ t
2), frequency is 1/ (t
1+ t
2), mean current is defined as J
pt
1/ (t
1+ t
2).Compare with DC electrodeposition, thickness and the ion concentration distribution of electrostatic double layer all change; While adding electrochemical polarization, reduce concentration polarization, the direct effect of generation is, the coating that pulse plating obtains than DC electrodeposition coating evenly, crystallization is finer and closely woven.Moreover, pulse plating also has: hardness and the wear resistance of (1) coating are all high; (2) solution dispersibility and covering power good; (3) decrease the super plating of part edge, coating distributing homogeneity is good, can save plating solution usage quantity.
Using Copper Foil as negative electrode, take platinized platinum as anode.Anticathode pre-treatment is by comprising anticathode sand papering, oil removing, pickling, preimpregnation copper after elder generation successively.This use sand papering can polish twice, and first time with flint paper such as 200 object sand paperings, can be used fine sandpaper, such as, can use WC28 abrasive paper for metallograph for the second time.This oil removing can first adopt chemical alkali liquor oil removing then to adopt the dehydrated alcohol oil removing of 95%.Wherein, chemical alkali lye consists of: 50 ~ 80g/LNaOH, 15 ~ 20g/LNa
3pO
4, 15 ~ 20g/LNa
2cO
3and 5g/LNa
2siO
3with 1 ~ 2g/LOP-10.Electrochemical deoiling detailed process is through treating oil removing negative electrode 15 ~ 40 DEG C of dipping 30s in chemical alkali lye.The pickling time is 1 ~ 2min, and the object of pickling is activation, specifically, removes the oxide film on plating piece top layer, makes the lattice of matrix completely exposed, be in active state.Pickling solution composition used is: 100g/L sulfuric acid and 0.15 ~ 0.20g/L thiocarbamide.The preimpregnation copper time is 1 ~ 2min, and solution composition used is: 100g/L sulfuric acid, 50g/L anhydrous cupric sulfate and 0.20g/L thiocarbamide.
The area ratio of step (2) Anodic and negative electrode is preferably 3:1.Ratio of cathodic to anodic area is crossed conference and is made it more easily passivation occur; Otherwise, then cathode copper sedimentation rate can be caused too small, thus reduce current efficiency.
The present invention with glucosamine hydrochlorate for coordination agent and with iminodiethanoic acid for helping coordination agent, both synergy and improve with gold coordination ability, take glycine as stablizer, avoid plating solution oxidation in acid condition; Take gold perchloride as the main salt of gold, make the plating solution of acquisition have good dispersion force and covering power thus, cathode efficiency is high, and plating solution performance is excellent.The porosity that employing electroplates the coating of acquisition in the basic conditions at plating solution is low, and luminance brightness is high, and quality of coating is good.
Embodiment
Technical scheme of the present invention is further illustrated below in conjunction with embodiment.
According to formulated electroplate liquid described in embodiment 1 ~ 6, specific as follows: the quality taking each feed composition according to formula electronic balance.Fully mix then after each feed composition is dissolved in appropriate deionized water respectively, add water move to pre-determined volume, add acid or alkali adjust ph is 4 ~ 6.
The electroplate liquid of formulated described in embodiment 1 ~ 6 and comparative example is used to carry out electric plating method:
(1) negative electrode adopts the Copper Foil of 10mm × 10mm × 0.1mm specification.Metalluster is exposed with the polishing of WC28 abrasive paper for metallograph to surface again after first tentatively being polished with 200 order waterproof abrasive papers by Copper Foil.Successively through temperature be 50 ~ 70 DEG C chemical alkali liquor oil removing, distilled water flushing, 95% dehydrated alcohol oil removing, distilled water flushing, pickling 1 ~ 2min, preimpregnation copper 1 ~ 2min, redistilled water rinse.Wherein, the formula of chemical alkali lye is 50 ~ 80g/LNaOH, 15 ~ 20g/LNa
3pO
4, 15 ~ 20g/LNa
2cO
3and 5g/LNa
2siO
3with 1 ~ 2g/LOP-10.Pickling solution composition used is: 100g/L sulfuric acid and 0.15 ~ 0.20g/L thiocarbamide.The solution composition used of preimpregnation copper is: 100g/L sulfuric acid, 50g/L anhydrous cupric sulfate and 0.20g/L thiocarbamide.
(2) with the platinum plate of 15mm × 10mm × 0.2mm specification for anode, by level and smooth for sand papering, deionized water rinsing and oven dry before plating.
(3) by the electroplate liquid in pretreated anode and negative electrode immersion plating groove, just plating tank is placed in thermostat water bath, and is plating tank installation electric blender, the stirring rod of electric blender is inserted in electroplate liquid.Bath temperature to be regulated makes temperature of electroplating solution maintain 50 ~ 60 DEG C, and after mechanical stirring rotating speed is adjusted to 100 ~ 250rpm, make pulse power supply, the pulsewidth of pulsed current is 0.5 ~ 1ms, and dutycycle is 5 ~ 30%, and average current density is 0.5 ~ 1A/dm
2.After 20 ~ 40min to be energised, cut off the power supply of electroplanting device.Take out steel plate, use distilled water cleaning, drying.
Embodiment 1
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 0.5ms, and dutycycle is 30%, and average current density is 0.5A/dm
2; PH is 4, and temperature is 60 DEG C, and electroplating time is 40min.
Embodiment 2
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 0.6ms, and dutycycle is 25%, and average current density is 0.6A/dm
2; PH is 4.5, and temperature is 60 DEG C, and electroplating time is 35min.
Embodiment 3
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 0.8ms, and dutycycle is 20%, and average current density is 1A/dm
2; PH is 5, and temperature is 50 DEG C, and electroplating time is 20min.
Embodiment 4
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 1ms, and dutycycle is 15%, and average current density is 0.9A/dm
2; PH is 6, and temperature is 50 DEG C, and electroplating time is 25min.
Embodiment 5
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 0.9ms, and dutycycle is 5%, and average current density is 0.8A/dm
2; PH is 5.5, and temperature is 55 DEG C, and electroplating time is 30min.
Embodiment 6
The formula of electroplate liquid is as follows:
Plating technology condition: the pulsewidth of monopulse rectangular wave current is 0.7ms, and dutycycle is 10%, and average current density is 0.7A/dm
2; PH is 5.2, and temperature is 55 DEG C, and electroplating time is 35min.
With reference to following methods, dispersive ability test is carried out to the plating solution of embodiment 1 ~ 6:
The dispersive ability of plating solution adopts far and near cathode method (Haring-Blue method) to measure.Measure the Hull groove that groove adopts the HullCell267ml model of Kocour company of the U.S., interior dimensions is 150mm × 50mm × 70mm.Negative electrode selects thickness to be the copper sheet of 0.5mm, and working face is of a size of 50mm × 50mm; Anode is plating nickel plate with holes; Plating electric current 1A, electroplating time 30min.
The dispersive ability calculation formula of plating solution is:
Dispersive ability=[K-(the Δ M of plating solution
1/ Δ M
2)]/(K-1) (result represents with percentage);
In formula, K is negative electrode far away to the distance of anode and nearly negative electrode to the ratio of distances constant of anode, and in this test, K gets 2; Δ M
1for the increment (g) after plating on nearly negative electrode; Δ M
2for the increment (g) after plating on negative electrode far away.
With reference to following methods, covering power test is carried out to the plating solution of embodiment 1 ~ 6:
Endoporus method is adopted to measure.Negative electrode selects internal diameter 110mm, and pipe range is the copper pipe of 50mm, and one end is closed.During test, the distance of the mouth of pipe and anode is fixed on 80mm, test current 0.2A, electroplating time 30min.According to following formulae discovery:
Covering power=endoporus coating length/pipe range (result represents with percentage).
With reference to following methods, current efficiency test is carried out to the plating solution of embodiment 1 ~ 6:
Copper voltameter method is adopted to measure.Negative electrode to be tested and copper voltameter cleaned and dry up rear electronic scale weighing, then insert in electrodeposit groove by two negative electrodes simultaneously, be energized 10 ~ 30min, take out and clean dry up after use electronic scale weighing.According to following formulae discovery:
Current efficiency=(1.186 × cathode quality to be measured)/(electrochemical equivalent of copper voltameter quality × cathodic deposition metal to be measured) × 100%.Here, electrochemical equivalent=molar mass ÷ (depositing ions valency × 26.8), unit is g.A
-1.h
-1.In this test, trivalent Au electrochemical equivalent is 2.453g.A
-1.h
-1.
Speed test is plated with reference to the plating solution of following methods to embodiment 1 ~ 6:
Mass method is adopted to measure sedimentation rate.Be 10 with sensitivity
-4electronic balance weighing sample plating before and after quality.By the acquisition sedimentation rate of poor quality of unit time, unit surface, press formulae discovery below:
Plating speed=(after plating before sample mass-plating sample mass)/(specimen surface to be plated long-pending × plating time).Each Data duplication is measured three times and is got its mean value.
Test with reference to the bonding force of following methods to the coating of embodiment 1 ~ 6:
The method adopting line to draw lattice measures the bonding force of coating, is specially: being 30 degree with one cutting edge by electrodeposition cladding, converted steel draws parallel lines or the 1mm that 2mm of being separated by drawn by cutter
2square lattice.Whether the coating observing line tilts or peels off.Should master the dynamics during line, a cutter just can scratch coating, arrives matrix metal.Adopt quench to measure the bonding force of coating, be specially: the test piece of having plated is placed in retort furnace quenching in the cold water being heated to 300 DEG C of insulation 30min taking-up immersion 10 DEG C immediately, observe coating and whether occur bubble and decortication phenomenon.
With reference to following methods, toughness test is carried out to the coating of embodiment 1 ~ 6:
Coating is stripped down, is bent to 180 °, and extrudes knee, observe coating and whether occur fracture.
With reference to following methods, porosity test is carried out to the coating of embodiment 1 ~ 6:
The large young pathbreaker of porosity is directly connected to the corrosion resisting property of coating, adopts paster method to press GB5935-86 standard detection.The etchant solution that the potassium ferricyanide solution of 10g/L and the sodium chloride solution of 20g/L are tested as porosity.Operation steps is: after wiped clean of being deoiled by coating surface, is close to coating surface with the filter paper soaking into etchant solution, and the two can not have gap.Buy the fully wetting filter paper of etchant solution solution by glass stick or degreasing swab stick, supplement a solution at interval of 1min, taken off by filter paper after 5min, dry after clean with distilled water flushing, record hole is counted.Be placed on cleaned glass plate and dry, the number of number Bluepoint.Substitute into formulae discovery voidage below:
Number/tested area (individual/the cm of porosity=spot
2);
When calculating number of apertures, do following calculating by spot diameter size: hot spot diameter is less than 1mm, and with a porosimeter at often; Be greater than 1mm and be less than 3mm often o'clock with three porosimeters; Be greater than 3mm and be less than 5mm, often with ten porosimeters.
With reference to following methods, Surface flat test is carried out to the coating of embodiment 1 ~ 6:
By the Hull groove of the HullCell267ml model with the Kocour company of the test piece U.S. after 200 order sand paperings evenly at 3A/dm
2dC current density carries out plating 10min at 25 DEG C of temperature, and whether then observe test piece has scratch.
To expose aptitude tests with reference to the coating of following methods to embodiment 1 ~ 6:
Adopt the Hull groove of the HullCell267ml model of Kocour company of the U.S. at 3A/dm
2after DC current density carries out plating 10min at 25 DEG C of temperature, observe the surface luminous intensity of coating.
The test result of the coating of embodiment 1 ~ 6 and comparative example and the performance of plating solution is as follows:
As can be seen from the above table, in embodiment 1 ~ 6, consider from the integration test effect of plating solution and coating, the dispersive ability of the formula plating solution of embodiment 6, covering power, current efficiency and plating speed, the porosity of coating and bonding force will be got well compared with other embodiment.Thus, this formula is screening formulation of the present invention, and the preferred plating conditions of its correspondence is the pulsewidth of monopulse rectangular wave current is 0.7ms, and dutycycle is 10%, and average current density is 0.7A/dm
2; PH is 5.2, and temperature is 55 DEG C, and electroplating time is 35min, and male and femal face is long-pending than being 3:1.
It should be noted that and understand, when not departing from the spirit and scope of accompanying claim the present invention for required protection, various amendment and improvement can be made to the present invention of foregoing detailed description.Therefore, the scope of claimed technical scheme is not by the restriction of given any specific exemplary teachings.
Below know-why of the present invention is described in conjunction with specific embodiments.These describe just in order to explain principle of the present invention, and can not be interpreted as limiting the scope of the invention by any way.Based on explanation herein, those skilled in the art does not need to pay performing creative labour can associate other embodiment of the present invention, and these modes all will fall within protection scope of the present invention.
Claims (9)
1. an electroplate liquid for glucosaminicacid cyanogen-less gold, is characterized in that, comprises in gold 10 ~ 15g/L gold perchloride, in glucosamine acid group 80 ~ 104g/L glucosamine hydrochlorate, 32 ~ 60g/L iminodiethanoic acid and 1 ~ 5g/L glycine.
2. electroplate liquid according to claim 1, is characterized in that, comprises in gold 12g/L gold perchloride, in glucosamine acid group 90g/L glucosamine hydrochlorate, 45g/L iminodiethanoic acid and 3g/L glycine.
3. electroplate liquid according to claim 1, is characterized in that, described glucosamine salt is one in glucosamine saccharic acid potassium, glucosamine Calciofon and glucosamine saccharic acid zinc or at least two kinds.
4. use the electroplate liquid electric plating method described in claim 1, it is characterized in that, comprise the following steps:
(1) electroplate liquid is prepared: in water, dissolve each feed composition form electroplate liquid, described often liter of electroplate liquid contains in gold 10 ~ 15g gold perchloride, in glucosamine acid group 80 ~ 104g glucosamine hydrochlorate, 32 ~ 60g iminodiethanoic acid and 1 ~ 5g glycine;
(2) insert with pretreated negative electrode and anode and pass into electric current in described electroplate liquid and electroplate.
5. want the method described in 4 according to right, it is characterized in that, described electric current is monopulse rectangular wave current; The pulsewidth of described monopulse rectangular wave current is 0.5 ~ 1ms, and dutycycle is 5 ~ 30%, and average current density is 0.5 ~ 1A/dm
2.
6. method according to claim 4, is characterized in that, in described step (2), the pH of electroplate liquid is 4 ~ 6.
7. method according to claim 4, is characterized in that, the temperature of electroplate liquid is 50 ~ 60 DEG C.
8. method according to claim 4, is characterized in that, the time of plating is 20 ~ 40min.
9. method according to claim 4, is characterized in that, the area ratio of described step (2) Anodic and negative electrode is (1 ~ 4): 1.
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|---|---|---|---|
| CN201410468824.1A CN105441995A (en) | 2014-09-15 | 2014-09-15 | Glucosaminic-acid cyanide-free gold-plating electroplating liquid and electroplating method thereof |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201410468824.1A CN105441995A (en) | 2014-09-15 | 2014-09-15 | Glucosaminic-acid cyanide-free gold-plating electroplating liquid and electroplating method thereof |
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ID=55552613
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|---|---|---|---|
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114108040A (en) * | 2020-08-25 | 2022-03-01 | 周大福珠宝文化产业园(武汉)有限公司 | Cyanide-free gold plating solution and gold electroforming part manufactured by cyanide-free electroplating process |
-
2014
- 2014-09-15 CN CN201410468824.1A patent/CN105441995A/en active Pending
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114108040A (en) * | 2020-08-25 | 2022-03-01 | 周大福珠宝文化产业园(武汉)有限公司 | Cyanide-free gold plating solution and gold electroforming part manufactured by cyanide-free electroplating process |
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Application publication date: 20160330 |