NaCl, MgCl2 ВА KCl TUZLARINING FIZIK-KIMYOVIY XUSUSIYATLARI VA ULARNI  QUYOSH HOVUZI QURILMASI ISSIQLIK SAMARADORLIGIGA TA’SIRINI TADQIQOT QILISH

Davlonov Xayrulla Allamurodovich; Elmurodov Nuriddin Sayitmurodovich; Toshboyev Abdimalik Rashid o'g'li

Ushbu maqolada quyosh hovuzining issiqlik yig‘ish samaradorligiga NaCl,

MgCl2va KCl tuzlari asosidagi sho‘r suvlari tasiri hamda ularning fizik-kimyoviy xususiyatlarini

aniqlashning eksperimental usuli tasvirlangan. Tajriba ishlari davomida ushbu tuzlarning zichlik

profilini o‘rnatish, konsentratsiyasi va issiqlik sig‘imlarini aniqlash maqsadida quyosh hovuzi

qurilmasida har bir tuzning alohida sho‘rli suv eritmalari tayyorlandi. Hovuzning turli

nuqtalaridan olingan namunalarni tadqiqot qilish asosida har bir tuzning zichlik profili o‘rganildi

hamda grafiklari qurildi. Tajriba uchun yasalgan adiabatik kolorometr yordamida 20оС-70оС

harorat oralig‘ida va sho‘r suv konsentratsiyasining 5 % - 28 % qiymatlarida har bir tuzli sho‘r

suvning issiqlik sig‘imlari o‘rganildi va turli haroratlarda o‘zgarish grafiklari keltirildi.

Журнал номиMUQOBIL ENERGETIKA
Нашр номи01 (08) 2023
Кўришлар сони 65

Internet ҳавола

DOI

UzSCI тизимида яратилган сана 15-09-2024

Ўқишлар сони 65

Нашр санаси 31-03-2023

Мақола тилиO'zbek

Саҳифалар сони52-59

Калит сўзлар

konsentratsiya

kaliy xlorid

magniy xlorid

natriy xlorid

zichlik profili

issiqlik sig‘im

Ўзбек

Ushbu maqolada quyosh hovuzining issiqlik yig‘ish samaradorligiga NaCl,

MgCl2va KCl tuzlari asosidagi sho‘r suvlari tasiri hamda ularning fizik-kimyoviy xususiyatlarini

aniqlashning eksperimental usuli tasvirlangan. Tajriba ishlari davomida ushbu tuzlarning zichlik

profilini o‘rnatish, konsentratsiyasi va issiqlik sig‘imlarini aniqlash maqsadida quyosh hovuzi

qurilmasida har bir tuzning alohida sho‘rli suv eritmalari tayyorlandi. Hovuzning turli

nuqtalaridan olingan namunalarni tadqiqot qilish asosida har bir tuzning zichlik profili o‘rganildi

hamda grafiklari qurildi. Tajriba uchun yasalgan adiabatik kolorometr yordamida 20оС-70оС

harorat oralig‘ida va sho‘r suv konsentratsiyasining 5 % - 28 % qiymatlarida har bir tuzli sho‘r

suvning issiqlik sig‘imlari o‘rganildi va turli haroratlarda o‘zgarish grafiklari keltirildi.

Калит сўзлар

konsentratsiya

kaliy xlorid

magniy xlorid

natriy xlorid

zichlik profili

issiqlik sig‘im

№ Муаллифнинг исми Лавозими Ташкилот номи

1 Davlonov X.A. t.f.f.d., dotsent QarMII

2 Elmurodov N.S. doktorant QarMII

3 Toshboyev A.R. o'qituvchi QarMII

№ Ҳавола номи

1 Farrokhi M. et al. Integration of a solar pond in a salt work in Sabzevar in Northeast Iran //Solar Energy. – 2022. – Т. 244. – С. 115-125.

2 Элмуродов Н. С. и др. Сузишбассейнларининг энергия баланситаҳлили //Инновационтехнологиялар. – 2022. – Т. 3. – №. 3 (47). – С. 21-27.

3 Uzakov G. N., Elmurodov N. S., Davlonov X. A. Experimental study of the temperature regime of the solar pond in the climatic conditions of the south of Uzbekistan //IOP Conference Series: Earth and Environmental Science. – IOP Publishing, 2022. – Т. 1070. – №. 1. – С. 012026.

4 Узоков Г., Элмуродов Н., Давлонов Х. Ўзбекистон жанубидаги иқлим шароитида қуёш ҳовузининг ҳарорат режимини экспериментал ўрганиш//Innovatsion texnologiyalar. – 2022. – Т. 1. – С. 97-102.

5 Sifuna D. B. Optimizing thermal storage efficiency of a salt gradient solar pond using polyethylene membrane: дис. – Egerton University, 2015.

6 Hull, J. R., Bushnell, D. L., Sempsorte, D. G. and Pena, A. (1989a). Ammonium sulphate solar pond: observation from small scale experiments. Journal of solar energy 43: 57-63.

7 Hull, J. R. Nielsen, C. E. and Golding, P. (1989b). Salinity-gradient solar ponds. Florida: CRC Press, Inc: 175-189.

8 Tabor, H. (1978). Solar ponds (non-convecting)’ in: Solar Energy Conversion - an introductory course. Toronto: Pergamon Press, Toronto, Canada: 167-183

9 Kaufmann D. W. Sodium chloride: the production and properties of salt and brine. – 1960.

10 Faqeha H. et al. An experimental study to establish a salt gradient solar pond (SGSP) //Energy Procedia. – 2019. – Т. 160. – С. 239-245.

11 Tabor H. Solar ponds //Solar energy. – 1981. – Т. 27. – №. 3. – С. 181-194.

12 Saxena A. K., Sugandhi S., Husain M. Significant depth of ground water table for thermal performance of salt gradient solar pond //Renewable Energy. – 2009. – Т. 34. – №. 3. – С. 790-793.

13 Murthy G. R. R., Pandey K. P. Scope of fertiliser solar ponds in Indian agriculture //Energy. – 2002. – Т. 27. – №. 2. – С. 117-126.

14 Hull JR, Physics of the Solar Pond, Ph.D, dissertation, Iowa State University, 1979

15 Zangrando F. Observation and Analysis of a Full-Scale Experimental Salt Gradient Solar Pond //Ph. D. Thesis. – 1979.

16 Sh H Ergashev et al 2022 IOP Conf. Ser.: Earth Environ. Sci. 1070 012031

Кутилмоқда

№	Муаллифнинг исми	Лавозими	Ташкилот номи
1	Davlonov X.A.	t.f.f.d., dotsent	QarMII
2	Elmurodov N.S.	doktorant	QarMII
3	Toshboyev A.R.	o'qituvchi	QarMII

№	Ҳавола номи
1	Farrokhi M. et al. Integration of a solar pond in a salt work in Sabzevar in Northeast Iran //Solar Energy. – 2022. – Т. 244. – С. 115-125.
2	Элмуродов Н. С. и др. Сузишбассейнларининг энергия баланситаҳлили //Инновационтехнологиялар. – 2022. – Т. 3. – №. 3 (47). – С. 21-27.
3	Uzakov G. N., Elmurodov N. S., Davlonov X. A. Experimental study of the temperature regime of the solar pond in the climatic conditions of the south of Uzbekistan //IOP Conference Series: Earth and Environmental Science. – IOP Publishing, 2022. – Т. 1070. – №. 1. – С. 012026.
4	Узоков Г., Элмуродов Н., Давлонов Х. Ўзбекистон жанубидаги иқлим шароитида қуёш ҳовузининг ҳарорат режимини экспериментал ўрганиш//Innovatsion texnologiyalar. – 2022. – Т. 1. – С. 97-102.
5	Sifuna D. B. Optimizing thermal storage efficiency of a salt gradient solar pond using polyethylene membrane: дис. – Egerton University, 2015.
6	Hull, J. R., Bushnell, D. L., Sempsorte, D. G. and Pena, A. (1989a). Ammonium sulphate solar pond: observation from small scale experiments. Journal of solar energy 43: 57-63.
7	Hull, J. R. Nielsen, C. E. and Golding, P. (1989b). Salinity-gradient solar ponds. Florida: CRC Press, Inc: 175-189.
8	Tabor, H. (1978). Solar ponds (non-convecting)’ in: Solar Energy Conversion - an introductory course. Toronto: Pergamon Press, Toronto, Canada: 167-183
9	Kaufmann D. W. Sodium chloride: the production and properties of salt and brine. – 1960.
10	Faqeha H. et al. An experimental study to establish a salt gradient solar pond (SGSP) //Energy Procedia. – 2019. – Т. 160. – С. 239-245.
11	Tabor H. Solar ponds //Solar energy. – 1981. – Т. 27. – №. 3. – С. 181-194.
12	Saxena A. K., Sugandhi S., Husain M. Significant depth of ground water table for thermal performance of salt gradient solar pond //Renewable Energy. – 2009. – Т. 34. – №. 3. – С. 790-793.
13	Murthy G. R. R., Pandey K. P. Scope of fertiliser solar ponds in Indian agriculture //Energy. – 2002. – Т. 27. – №. 2. – С. 117-126.
14	Hull JR, Physics of the Solar Pond, Ph.D, dissertation, Iowa State University, 1979
15	Zangrando F. Observation and Analysis of a Full-Scale Experimental Salt Gradient Solar Pond //Ph. D. Thesis. – 1979.
16	Sh H Ergashev et al 2022 IOP Conf. Ser.: Earth Environ. Sci. 1070 012031