"L.I. Medved’s Research Center of preventive Toxicology, Food and Chemical Safety, Ministry of Health, Ukraine" (State Enterprise), Kyiv, Ukraine

Abstract. In recent decades, the world has faced a new environmental problem ‒ waste electrical and electronic equipment (WEEE). Timely prevention of the formation of WEEE, minimization of their volume, reuse, recycling and recovery of resources ‒ all these issues require urgent appropriate solutions.

Aim. Determining the degree of hazard of waste galvanic elements (batteries) and assigning this waste to the category of hazardous or safe according to national norms and rules.

Materials and Methods. Waste galvanic cells (batteries) were the object of research. The samples were dissolved in concentrated nitric acid. The solutions were diluted with distilled water, filtered, and then the content of heavy metals was determined according to DSTU ISO 11885:2005 "Water quality. 33 elements were determined by the method of atomic emission spectrometry with inductively coupled plasma" (ISO 11885:1996, IDT) and GOST 30178-96 "Raw materials and food products. Atomic absorption method for determination of toxic elements". Determination of elements was carried out on an optical emission spectrometer with an inductively coupled plasma "SHIMADZU ICPE-9820".

Research results. It was established that the content of lead, cadmium, mercury in waste galvanic elements (batteries) does not exceed the established hygienic standards for the soil ("Hygienic regulations of the permissible content of chemical substances in the soil", Order of the Ministry of Health of Ukraine No. 1595 dated 14.07.2020). Mercury: in 25 samples it was detected at a level that is lower than the sensitivity of the method, in two samples it is 2.25 times and 4.2 times less than the Limit Permissible Concentrations (LPC); in four ‒ 27-48.8 times less, in three ‒ 58-91 times less. The LPC of mercury in soil is 2.1 mg/kg. Cadmium: in 1 sample it was detected at a level that is lower than the sensitivity of the method, in 26 samples it is 2-7.5 times less than the LPC; in the 7th ‒ 9-30 times less. The LPC of cadmium in soil is 1.5 mg/kg. Lead: in 13 samples it was detected at a level that is lower than the sensitivity of the method, in 2 samples it was 3 times less than the LPC, in 6 samples it was 12-19.4 times less than the LPC, in 13 samples ‒ in 24-31 times less than LPC. Maximum permissible limit for lead in soil is 32 mg/kg. It was established that the examined waste samples of galvanic elements (batteries) can be classified as safe and processed and disposed of at the appropriate enterprise.

Conclusions. The negative effect of WEEE components on the environment and, as a result, on human health is associated with the inevitable risk of their entering environmental objects due to improper handling of waste galvanic elements (batteries). In order to prevent and minimize the risk to the environment and the population, it is necessary to introduce selective sorting of WEEE components at the places of their generation or collection and sending them for processing, as well as to develop sanitary and epidemiological requirements for sorting processes and to carry out an examination of projects and installations for the utilization of such types of waste for compliance these requirements.

Key Words: waste electrical and electronic equipment, waste batteries and accumulators, hazard assessment.

СПИСОК ВИКОРИСТАНИХ ДЖЕРЕЛ / REFERENCES

1. Shumylo O.M, Vyhovska H.P, Tsyhulova O.M, Poviakel L.I, Snoz S.V. Vyrishennia problemy elektronnykh vidkhodiv: yevropeiski pidkhody do ukrainskoi problemy, K., FOP «Klymenko», 2013: 87 s.

2. Poviakel L.I., Snoz S.V., Smerdova L.M., Kryvenchuk V.Ye, Bobylova O.O. Vazhki metaly yak faktor ryzyku dlia zdorov’ia liudyny ta dovkillia pry povodzhenni z vidkhodamy elektrychnoho ta elektronnoho obladnannia.Suchasni problemy toksykolohii, kharchovoi ta khimichnoi bezpeky; 2015;1/2 (68/69):41-49.

3. DIRECTIVE 2006/66/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL of 6 September 2006 on batteries and accumulators and waste batteries and accumulators and repealing Directive 91/157/EEC.

4. REPORT FROM THE COMMISSION TO THE EUROPEAN PARLIAMENT, THE COUNCIL, THE EUROPEAN ECONOMIC AND SOCIAL COMMITTEE AND THE COMMITTEE OF THE REGIONS on the implementation and the impact on the environment and the functioning of the internal market of Directive 2006/66/EC of the European Parliament and of the Council of 6 September 2006 on batteries and accumulators and waste batteries and accumulators and repealing Directive 91/157/EEC Brussels, 9.4.2019 COM(2019) 166 final - 7 p.

5. COMMISSION STAFF WORKING DOCUMENT on the evaluation of the Directive 2006/66/EC on batteries and accumulators and waste batteries and accumulators and repealing Directive 91/157/EEC Brussels, 9.4.2019 SWD(2019) 1300 final – 86 p.

6. Zbysław Dobrowolski, Łukasz Sułkowski and Wiesław Danielak Management of Waste Batteries and Accumulators: Quest of European Union Goals// Energies 2021, 14, 6273.  https://doi.org/10.3390/en14196273.

7. Yong Choi, Seung-Whee Rhee Current status and perspectives on recycling of end-of-life battery of electric vehicle in Korea (Republic of)// Waste Management - Volume 106, 1 April 2020, r. 261-270, https://doi.org/10.1016/j.wasman.2020.03.015.

8. Environmental Health Criteria (EHC) Monograph 85. Lead: environmental aspects/WHO, Geneva. 1989.

9. Lead and lead compounds. IARC Monograph. Supplement 7 (1987): 230.

10. Environmental Health Criteria (EHC) Monograph 1. Mercury/WHO, Geneva, 1976.

11. Environmental Health Criteria (EHC) Monograph 86. Mercury - environmental aspects / WHO, Geneva, 1989.

12. Mercury and mercury compounds. IARC Monograph. 1993; v.58: 239.

13. Environmental Health Criteria (EHC) Monograph 135. Cadmium‒environmental aspects / WHO, Geneva. 1992.

14. Cadmium and cadmium compounds. IARC Monograph. (1993); v.58: 119.

Стаття надійшла до редакції 08.09.2022 р. / Received September 08, 2022.