Continuous copper leaching technology


Chimica Techno Acta LETTER 
published by Ural Federal University 2021, vol. 8(1), № 20218109 
journal homepage: chimicatechnoacta.ru DOI: 10.15826/chimtech.2021.8.1.09 

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Continuous copper leaching technology 

L.I. Mukhortova
*
, O.E. Nasakin, A.V. Eremkin, I.V. Glushkov 

Federal State Budgetary Institution of Higher Education "Chuvash State University  
named after I.N. Ulyanov ", 19 Moskovsky Ave., Cheboksary, Russia, 428015 
* Corresponding author: mlimait@rambler.ru 

This short communication (letter) belongs to the MOSM2020 Special Issue. 

© 2021, The Authors. This article is published in open access form under the terms and conditions of the Creative 

Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/). 

 

Abstract 

The parameters of the continuous technological process of leaching 
copper from fine copper waste using nitric acid as an oxidizer are 
studied. Optimal conditions for a continuous leaching process were 
established, in which solutions with a mass concentration of copper 
ions greater than 25 g/dm

3
 were obtained. 

Keywords 
copper leaching 

copper waste treatment 

Received: 20.10.2020 

Revised: 25.12.2020 

Accepted: 25.12.2020 

Available online: 13.04.2021 

 

1. Introduction 

Copper is one of the most popular metals for human eco-

nomic activity and has been used since ancient times. In 

the global structure of copper consumption, 30% is used 

in construction, 30% for equipment production, 13% - in 

the transport industry, and the remaining 27% is distrib-

uted among other sectors of the economy. In 2019 there 

were produced 23.72 million tons of copper. In the copper 

market, Russia provides about 4.7% of world production. 

Currently, there is an excess of demand over supply in the 

amount of 94 thousand rubles·tons and according to ana-

lysts ' estimates, a further increase in demand for copper 

is forecast [1]. 

Unfortunately, the extraction of copper from natural 

sources is expensive and not very environmentally friend-

ly, so it is more cost-effective to get copper from copper 

waste. 

Hydroelectrometallurgical processes are widely used 

for processing copper waste to produce metallic copper. 

These processes can be divided into electrolytic refining 

and electroextraction [2,3]. Electrolytic refining is used as 

the final stage in pyrometallurgical processes for produc-

ing copper, including the processing of copper waste by 

melting. The technology of this process is well studied and 

covered in detail in many monographs and textbooks. As a 

result of electrofining, cathode copper with a purity of 

99.7–99.9% and a spent electrolyte are obtained, in which 

copper sulfate and impurities of other metals accumulate. 

The spent electrolyte is periodically sent for regeneration, 

which is a process of electrical extraction of copper. Elec-

troextraction is carried out in electrolyzers with an insol-

uble anode. 

The electroextraction method can also be used for pro-

cessing copper waste from previously obtained solutions 

of copper salts. 

It is known that copper dissolves only in the presence 

of substances with oxidizing properties: concentrated sul-

furic acid, oxygen, hydrogen peroxide and nitric acid. High 

values of redox potentials of nitric acid solutions allow 

dissolving copper. With concentrated nitric acid (mass 

fraction of acid more than 45%), the reaction proceeds 

according to equation (1), and with dilute acid (mass frac-

tion of acid less than 40 %) – according to equation (2) 

[4]: 

Cu + 4HNO3 → Cu(NO3)2 + 2NO2 + 2H2O, (1) 

3Cu + 8HNO3 → 3Cu(NO3)2 + 2NO + 4H2O. (2) 

In this paper, the possibility of conducting a continu-

ous process of copper dissolution with nitric acid while 

excluding the formation of toxic nitrogen dioxide is stud-

ied. 

2. Experimental 

The diagram of the experimental laboratory installation is 

shown in Fig. 1 

A cylindrical reactor 1 with a diameter of 50 mm and a 

height of 250 mm with a false bottom located at a height 

of 20 mm has a jacket heated by water vapor obtained in a 

laboratory steam generator 5. Copper chips with a particle 

size of about 2×2×2 mm were loaded into the reactor until 

a 200 mm high copper column was obtained. Seven com-

positions of working solutions with different fixed concen-

trations of nitric acid were prepared for the experiments 

10, 15, 20, 25, 30, 40 and 45% (mass). Before each exper-

iment, working solutions with a volume of 500 cm
3
 were 

prepared, heated to a set temperature and thermostated. 

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Chimica Techno Acta 2021, vol. 8(1), № 20218109 LETTER 

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1

4 5

2

3

Initial working 

solution
Waste gas

Steam

Ready solutionNitrogen

 
Fig. 1 Scheme of an experimental laboratory installation:  

1 – a tank for preparing the working solution; 2 – a reactor with 
loaded copper chips; 3– a jacket for heating the reactor; 4 – a 

steam generator; 5 – an absorption tank 

To stabilize the temperature in the reactor, the reactor 

was initially filled with water, the water was heated to a 

set temperature by applying steam to the jacket, then the 

water was drained and a hot working solution was imme-

diately supplied. The working solution was fed to the up-

per part of the reactor through a sprinkler. The contact 

time was regulated by the flow rate of the working solu-

tion from 60 to 300 cm
3
/s. The liquid level in the reactor 

was regulated by lowering the finished solution. The first 

50 cm
3
 of the finished solution was discarded. The content 

of copper ions in the solution was controlled by the iodo-

metric method [5]. Waste gases from the reactor were 

displaced by a nitrogen current into an absorption flask 

filled with 50 cm
3
 of a 10% solution of potassium iodide. 

At the end of the experiment, a qualitative test was made 

for the content of nitrogen dioxide in the absorption solu-

tion for the formation of pink staining with the Griess-

Ilosvaya reagent [6]. 

To obtain reliable results, all experiments were repeat-

ed three times and the arithmetic mean values of the 

measurement results were calculated. In each experiment, 

the reactor was filled with a new sample of copper and a 

freshly prepared working solution was used. The relative 

error of the results does not exceed ±5%. 

3. Results and Discussion 

The main criteria for the effectiveness of the process of 

leaching copper with nitric acid are the concentration of 

copper ions in the solution at the reactor outlet and the 

formation of nitrogen dioxide.  

During the experiment, it was found that the solubility 

of copper is mainly influenced by three factors: the con-

tact time, the concentration of nitric acid and the tempera-

ture of the solution.  

To determine the optimal contact time, experiments 

were performed with a working solution containing 30% 

nitric acid when the temperature and flow rate of the solu-

tion changed (Fig. 2). 

The data presented in Fig. 2 show that the solubility of 

copper increases with decreasing consumption of the 

working solution and, accordingly, with increasing contact 

time. It follows that in production conditions, when the 

process is carried out in an industrial reactor, the efficien-

cy of the leaching process will increase, since the contact 

time will increase at the same costs. It should be noted 

that at the same flow rates, the dissolution rate increases 

with increasing temperature and reaches a maximum val-

ue at 60 °C. 

To determine the effect of nitric acid in the working so-

lution on the amount of dissolved copper at a constant 

flow of the working solution of 60 cm
3
/s, experiments 

were conducted which varied the temperature and compo-

sition of the working solution found that the mass fraction 

of nitric acid, 10 and 15% copper is not dissolved even 

when the temperature rises to 80 °C. 

With a further increase in the concentration of nitric 

acid in the solution, the solubility of copper increases 

(Fig. 3). 

The results show that with an increase in the content 

of nitric acid in the working solution, the rate of copper 

dissolution also increases, but with a mass fraction of ni-

tric acid of 40% and 45%, the absorption solution turns  

 
Fig. 2 Dependence of the concentration of copper ions in the solu-

tion on the flow rate of the working solution and temperature:  
a – 20 °C; b – 30 20 °C; c – 40 °C; d – 50 °C; e – 60 °C 

 
Fig. 3 Dependence of the concentration of copper ions in the solu-

tion on the content of nitric acid and the temperature of the solu-
tion: a – 20 °C; b – 30 20 °C; c – 40 °C; d – 50 °C; e – 60 °C  



Chimica Techno Acta 2021, vol. 8(1), № 20218109 LETTER 

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pink when the Griss–Ilosvay reagent is added, which indi-

cates the formation of nitrogen dioxide. Therefore, it is 

optimal to use working solutions with a mass fraction of 

nitric acid of 30-35%. An increase in temperature also 

contributes to an increase in the rate of the copper oxida-

tion reaction, but at temperatures above 60 °C, there is a 

significant entrainment of nitric acid with the nitrogen 

current and the cost of heat energy increases. 

4. Conclusions 

The experimental data obtained show that the process of 

copper leaching can be carried out in a continuous manner 

to produce solutions containing more than 25 g/dm
3
 of 

copper ions. It was found that the maximum concentration 

of copper ions without the formation of nitrogen dioxide is 

achieved when using working solutions with a mass frac-

tion of nitric acid of 25-30%, a temperature of 60 °C and a 

flow rate of 60 cm
3
/s of the working solution. 

5. References 

1. WBMS: proizvodstvo medi v 2019 godu neznachitel’no vy-

roslo [WBMS: copper production in 2019 increased insignifi-
cantly] [Internet]. Moscow: JSC “Metallservis”; c2020 [cited 

2020 Oct 10]. Russian. Available from: 

https://mc.ru/news/nw/news_id/11688 

2. Naboichenko SS. Smirnov VI. Gidrometallurgiya medi  
[Hydrometallurgy of copper]. Moscow: Metallurgiya; 1974. 

272 p. Russian. 

3. Bredikhin VN, Manyak NK, Kaftanenko AYa. Med’ vtorichna-
ya: monografiya [Secondary Copper: monograph]. Donetsk: 

DonNTU; 2006. 416 p. Russian. 

4. Lidin RA, Molochko VA, Andreeva LL. Khimicheskie svoystva 
neorganicheskikh veshchestv [Chemical properties of inor-

ganic substances]. Moscow: Khimiya; 2000. 408 p. Russian. 

5. Lurie YY. Analiticheskaya khimiya promyshlennykh sto-
chnykh vod [Analytical chemistry of industrial waste waters]. 

Moscow: Khimiya; 1984. 448 p. Russian. 

6. Bykhovskaya MS, Ginzburg SL, Halizova OD. Metody opre-
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[Methods for determining harmful substances in the air and 

other environments]. Moscow: Medgiz; 1960. 312 p. Russian. 

https://mc.ru/news/nw/news_id/11688