Arsenic removal from electrolytes with application of periodic reverse current

Information

  • Patent Grant
  • 4083761
  • Patent Number
    4,083,761
  • Date Filed
    Monday, August 2, 1976
    48 years ago
  • Date Issued
    Tuesday, April 11, 1978
    46 years ago
Abstract
A method is provided for removing arsenic from arsenic and copper containing electrolytes by electrolysis while minimizing the formation of arsine gas, through the application of a periodic reverse current during such electrolysis. The method is particularly suitable for the purification of copper refinery electrolyte.
Description

This invention relates to a novel method of removing arsenic from arsenic and copper containing electrolytes by electrolysis while minimizing the formation of toxic arsine gas. More particularly, the method provides for the application of a periodic reverse current during electrolysis leading to deposition of arsenic, copper and eventually other metallic elements present in the electrolyte onto the cathode while substantially reducing the formation of arsine gas which would normally be formed at the cathode under the same electrolysis conditions, but with the conventional application of direct current.
The novel method is particularly suitable for the purification of copper refinery electrolyte.
The use of periodic reverse current has been well known in the electroplating industry for a good number of years. For example, in U.S. Pat. No. 1,534,709, issued to F. A. Holt on Apr. 21, 1925, there is described a method of conducting electrolytic operations in which periodic reversal of the current is used to depolarize the electrodes during the electroplating of copper from an acid bath at high current density. U.S. Pat. Nos. 2,451,341 of Oct. 12, 1948 and 2,575,712 of Nov. 20, 1951, both in the name of G. W. Jernstedt, describe other methods of electroplating of metals selected from the group consisting of copper, brass, silver, zinc, tin, cadmium and gold with the use of periodic reverse current.
It is also known to use periodic reverse current in the electrolytic refining of copper as described, for example, in British patent specification No. 1,157,686 in the name of Medodobiven Kombinat "Georgi Damianov," published on July 9, 1969, and U.S. Pat. Nos. 3,824,162 of July 16, 1974 to Kenichi Sakii et al and 3,864,227 of Feb. 4, 1975 to Walter L. Brytczuk et al.
Furthermore, there are also known processes for applying periodic reverse current for the electrowinning of copper (Canadian Patent No. 876,284 of July 20, 1971 to Donald A. Brown et al) and for the electroextraction of zinc (Canadian Patent No. 923,845 of Apr. 3, 1973 to Ivan D. Entshev et al).
The present applicants have now found a new and a very surprising application of periodic reverse current for the purpose of removing arsenic from arsenic and copper containing electrolytes while minimizing the formation of toxic arsine gas which is a constant health hazard in such operations.
It is well known, for example, that, during electro-refining of impure copper, the impurities present in the anode are either dissolved into the solution as soluble compounds or precipitated in the form of insoluble compounds. To avoid contamination of the cathode copper, it is essential to control the concentration of undesired soluble impurities by purification of the electrolyte. Such electrolyte purification is carried out by passing a part of the tankhouse solution through the so-called liberator cells containing insoluble anodes, such as anodes made of lead or lead alloys, whose main purpose is to control the copper level of the electrolyte. After partial decopperization of the electrolyte, the solution is directed into purification cells, which are electrowinning cells where copper is depleted to low levels and, meanwhile, arsenic, antimony, bismuth, and possible other impurities are co-deposited onto the cathode, thus providing a means of controlling the concentration of these impurities in the electrolyte. During this co-deposition, arsenic is reduced at the cathode to its metallic form and at low copper concentrations to its hydride form, thus liberating the toxic arsine gas. The liberation of this arsine gas presents a major problem for every copper refinery in the world since it constitutes a constant health hazard to its workers. It is known that arsine gas is extremely toxic and an exposure thereto in a concentration of 250 ppm for 30 minutes is fatal while exposure to concentrations as low as 10 ppm can cause poisoning symptoms in a few hours (cf. American Conference of Governmental Industrial Hygienists: Threshold Limit Values for 1964, AMA Arch. Environ. Health 9:545 (1964)). It is, therefore, extremely important to minimize the evolution of arsine gas in all operations involving electrodeposition of arsenic from electrolytic solutions. A good agitation of the electrolyte as well as application of low current densities and high electrolyte temperatures have been found to decrease the rate of arsine gas formation. However, these methods alone are not sufficient in themselves and, consequently, they are normally accompanied by a strong ventilation system to avoid dangerous concentrations of the toxic arsine gas close to the purification cell. Obviously, such ventilation system merely transports the toxic gas from one place to another, namely from the workroom to the atmosphere and this may be found unacceptable by the ever stricter anti-pollution regulations implemented by the various governmental authorities. Furthermore, ventilation systems are prone to breakage and require a great deal of maintenance. The process of the present invention minimizes the formation of the arsine gas at the source, namely at the cathode and, consequently, to a great extent obviates the disadvantages encountered heretofore.
Basically, therefore, the present invention provides a method of removing arsenic from arsenic and copper containing electrolytes, which comprises carrying out an electrodeposition of the arsenic on a cathode by applying through the electrolyte a suitable direct current and periodically reversing the polarity of the current such as to minimize the formation of arsine gas at the cathode during such electrodeposition.
The electrolyte is preferably an acidic electrolyte, such as, for example, an aqueous solution containing sulphuric acid and copper ions therein. This electrolyte is also preferably maintained at a temperature between about 50.degree. and 75.degree. C during the electrodeposition and is also preferably circulated at an adequate rate which is usually in the range of about 40 to 70 U.S. gallons per minute for cells having a cathode surface area of about 1,000 square feet each. Lower or higher rates could also be suitable and the novel process is certainly not restricted by the preferred flow rates mentioned above.
The initial arsenic concentration of the electrolyte can vary within a wide range; for example, it can extend from less than 1 gram per liter to about 30 grams per liter. This is the normal range for arsenic containing electrolytes occurring in industry. Furthermore, the anode used in such electrodeposition is preferably an insoluble anode, for instance, made of lead or lead alloys, while the cathode is usually made of a metal such as copper or stainless steel.
The current density normally applied during such electrodeposition would vary between about 5 and about 30 amps. per square foot, the forward current being applied during periods of 5 - 30 seconds while the reverse current during periods of 1 - 4 seconds alternating with the forward current application. The ratio of the duration of reversed to forward current application is usually between 1/2 and 1/10.
In its most preferred embodiment, the present application provides a method of purification of copper refinery electrolyte, which comprises passing the electrolyte through electrolytic cells containing insoluble anodes, applying a direct current through these cells so as to co-deposit copper, arsenic, antimony and bismuth present in the electrolyte onto cathodes in these cells, and periodically reversing the polarity of the current such as to minimize formation of arsine gas during the co-deposition of copper and arsenic onto the cathodes. Under these conditions the electrolyte entering the cells in which the polarity is periodically reversed will usually contain about 6 to about 12 grams per liter of Cu and about 4 to about 8 grams per liter of arsenic and the co-deposition of copper and arsenic will be permitted to proceed until the electrolyte leaving the cells contains between about 0.3 and about 1 gram per liter of Cu and between about 1 and about 2 grams per liter of As.
In this operation, each of the cells employed has a cathode surface area of about 1,000 square feet and contains about 1,400 U.S. gallons of electrolyte. The flow rate of the electrolyte through these cells is preferably maintained between about 40 and about 70 gallons per minute during the co-deposition of copper and arsenic onto the cathodes which are preferably made of copper starting sheets. The temperature of the electrolyte is also preferably maintained between about 50.degree. C and about 75.degree. C and the current density between about 10 and about 25 amps. per square foot.
It is also possible to vary the current density during the co-deposition of copper and arsenic. Thus, the initial current density may preferably be maintained near the lower limit of about 10 amps. per square foot and, after a few hours of operation, it can be increased to near the higher limit of about 25 amps. per square foot, without producing any substantial increase in the arsine gas evolution.
Again, the forward polarity may be applied for periods of 5 to 30 seconds while the reverse polarity for periods of 1 to 4 seconds with the ratio of reverse to forward polarities being between 1/2 and 1/10.
In addition to arsenic and copper, the electrolyte entering the cells will usually contain small amounts (about 0.1 to about 0.4 grams per liter) of Sb and of Bi and the electrolyte leaving these cells will have reduced each of these elements to about 0.01 - 0.05 grams per liter.





The invention will now be described with reference to the following non-limitative examples which illustrate the preferred operating conditions as well as the advantages of the novel process.
EXAMPLES 1 TO 11
Eleven experimental examples of the purification of electrolyte under periodic reverse current (P.R.C.) and direct current (D.C.) electrolysis conditions were carried out on a laboratory scale in a cell of a 40 liter volume using copper starting sheets as the cathodes and lead-antimony insoluble anodes.
The electrolyte feed rate into the cell was 21 ml/min and the electrolyte was circulated in said cell at a rate of 800 ml/min while the temperature of the electrolyte was maintained at 65.degree. C.
The first eight examples were carried out under P.R.C. conditions having the following characteristics:
Forward current (I.sub.f) = 62 amps. (corresponding to 21 amps. per square foot current density).
Reverse current (I.sub.r) = 36 amps. (corresponding to 12.2 amps. per square foot current density).
Forward time (T.sub.f) = 10 seconds.
Reverse time (T.sub.r) = 2 seconds.
The last three examples, namely examples 9, 10 and 11, were carried out under D.C. conditions with the direct current (I) = 30 amps. (corresponding to 10 amps. per square foot current density).
The results obtained under these experimental conditions were then extrapolated to a full scale plant application for eighteen operational cells, each having about 1,000 square feet in cathode surface area and containing about 1,400 U.S. gallons of electrolyte, and 5 days of 16 hours plus 2 days of twenty four hours per week of normal operation.
The actual results of the experiments are given in Table I hereafter and the extrapolated full scale plant results are given in Table II hereafter.
TABLE I__________________________________________________________________________RESULTS OF PURIFICATION EXAMPLES CARRIED OUT UNDER PRC AND DCELECTROLYSIS CONDITIONS Feed Rate = 21 ml/min (corresponding to 33.7 USG/min for full scale plant) PRC: I.sub.f = 62 Amp (21 asf) I.sub.r = 36 Amp (12.2 asf) T.sub.f = 10 seconds T.sub.r = 2 seconds Electrolyte Temperature: 65.degree. C Electrolyte Recirculation Rate: 800 ml/min (corres- DC: I = 30 Amp (10 asf) ponding to 71.5 USG/min for full scale plant) AsH.sub.3 EmissionType Cu As Sb Bi mg/amp.hrEx. of [Cu] gpl gCu/ % [As] gpl gAs/ [Sb] gpl gSb/ [Bi] gpl gBi/ UpperNo. Current In Out Amp.hr C.E. In Out Amp.hr In Out Amp.hr. In Out Amp,.hr. Limit.sup.3__________________________________________________________________________ 71 PRC 7.35 0.43 0.141 11.86 5.98 3.25.sup.1 0.168.sup.2 0.220 0.101.sup.1 0.0043.sup.2 0.105 0.018.sup.1 0.0018.sup.2 <0.00052 PRC 7.35 0.46 0.139 11.80 5.98 2.50.sup.1 0.127.sup.2 0.220 0.078.sup.1 0.0029.sup.2 0.105 0.01 0.0019 <0.00053 PRC 8.90 0.46 0.171 14.46 5.83 1.80.sup.1 0.097.sup.2 0.216 0.058.sup.1 0.0032.sup.2 0.105 0.01 0.0019 <0.00054 PRC 11.15 0.51 0.215 18.2 5.50 1.55.sup.1 0.096.sup.2 0.216 0.05 0.0037 0.105 0.01 0.0019 <0.00055 PRC 5.65 0.31 0.108 9.15 5.75 1.42.sup.1 0.116.sup.2 0.210 0.04 0.0034 0.109 0.01 0.0020 <0.00056 PRC 3.25 0.18 0.062 5.26 5.87 1.23 0.097 0.218 0.03 0.0038 0.106 0.01 0.0020 <0.00057 PRC 7.70 0.27 0.150 12.70 5.45 1.17 0.087 0.214 0.03 0.0037 0.102 0.01 0.0019 <0.00058 PRC 7.80 0.31 0.152 12.83 7.50 1.21.sup.1 0.097.sup.2 0.224 0.03 0.0039 0.106 0.01 0.0020 <0.00059 DC 8.50 0.38 0.341 28.74 6.10 1.19 0.206 0.246 0.03 0.0091 0.118 0.01 0.0045 0.38410 DC 10.90 0.40 0.441 37.2 5.50 1.18 0.181 0.234 0.02 0.0090 0.122 0.01 0.0047 0.24611 DC 11.00 0.6 0.345 29.0 2.0 0.55 0.048 not de- not de- not de- not 3.0.sup.4 termined termined termined termined__________________________________________________________________________ .sup.1 Equilibrium of the metal species has not yet been reache290000000000000000000000000000000000000000000000000000000000000000
US Referenced Citations (4)
Number Name Date Kind
1534709 Holt Apr 1925
2606147 Chester Aug 1952
3824162 Sakai et al. Jul 1974
3864227 Brytczuk et al. Feb 1975
Non-Patent Literature Citations (1)
Entry
Kirk-Othmer Encyclopedia of Chem. Technology, 2nd Ed. 1963, pp. 163, 719.