YER OSTI ISSIQLIK ALMASHINUV QURILMALARINING MATEMATIK MODELLARI TAHLILI

Xamrayev Sardor Ilxomovich; Ibragimov Umidjon Xikmatullayevich

Binolarni isitish va sovitish tizimlarida qayta tiklanadigan energiya manbai sifatida geotermal energiya manbalari keng qoʻllaniladi. Yer osti issiqlik almashinuv qurilmalarining issiqlik xarakteristikasi geotermal issiqlik nasoslarini (GIN) samarali ishlashi uchun eng muhim hisoblanadi. Ushbu maqolada yirik GIN tizimlarda keng qoʻllaniladigan uchta turdagi, vertikal quduqli GIN, qoziqli GIN va gorizontal quduqli GINlari boʻyicha soʻnggi ishlanmalar tahlili keltirilgan. Shuningdek, turli geologik sharoitlarni inobatga olgan holda issiqlik uzatish jarayonlarini tadqiqot qilish uchun taklif etilgan analitik va sonli modellarining tahlillari keltirilgan

Name of journalИнновацион технологиялар
Number of edition2024/2(54)
View count 7

Web Address

DOI

Date of creation in the UzSCI system 14-09-2024

Read count 7

Date of publication 27-06-2024

Main LanguageO'zbek

Pages120-127

Tags

vertikal quduqli geotermal issiqlik nasoslari

gorizontal quduqli issiqlik nasoslari

isitish va sovitish

geotermal issiqlik nasoslari

Ўзбек

Binolarni isitish va sovitish tizimlarida qayta tiklanadigan energiya manbai sifatida geotermal energiya manbalari keng qoʻllaniladi. Yer osti issiqlik almashinuv qurilmalarining issiqlik xarakteristikasi geotermal issiqlik nasoslarini (GIN) samarali ishlashi uchun eng muhim hisoblanadi. Ushbu maqolada yirik GIN tizimlarda keng qoʻllaniladigan uchta turdagi, vertikal quduqli GIN, qoziqli GIN va gorizontal quduqli GINlari boʻyicha soʻnggi ishlanmalar tahlili keltirilgan. Shuningdek, turli geologik sharoitlarni inobatga olgan holda issiqlik uzatish jarayonlarini tadqiqot qilish uchun taklif etilgan analitik va sonli modellarining tahlillari keltirilgan

Tags

vertikal quduqli geotermal issiqlik nasoslari

gorizontal quduqli issiqlik nasoslari

isitish va sovitish

geotermal issiqlik nasoslari

№ Author name position Name of organisation

1 Xamrayev S.I. texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent, Qarshi muhandislik-iqtisodiyot instituti

2 Ibragimov U.X. texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent, Qarshi muhandislik-iqtisodiyot instituti

№ Name of reference

1 J.W. Lund, A.N. Toth, Direct utilization of geothermal energy 2020 worldwide review, Geothermics 90 (2021) 101915.

2 Khamraev S.I, Ibragimov U.Kh, Kamolov B.I. Removal of hydrodynamic lesions of a heated floor with a solar collector // APEC-V-2022 IOP Conf. Series: Earth and Environmental Science 1070(2022) 012018 IOP Publishing doi:10.1088/1755-1315/1070/1/012018.

3 Uzakov G. N., Charvinski V. L., Ibragimov U. Kh., Khamraev S.I., Kamolov B. I. (2022) Mathematical Modeling of the Combined Heat Supply System of a Solar House. Energetika. Proc. CIS Higher Educ. Inst. and Power Eng. Assoc. 65 (5), 412–421. https://doi.org/10. 21122/1029-7448-2022-65-5-412-421.

4 Y. Yuan, X. Cao, L. Sun, et al., Ground source heat pump system: a review of simulation in China, Renew. Sustain. Energy Rev. 16 (9) (2012) 6814–6822

5 H. Yang, P. Cui, Z. Fang, Vertical-borehole ground-coupled heat pumps: a review of models and systems, Appl. Energy 87 (1) (2010) 16–27.

6 M. Li, A.C.K. Lai, Review of analytical models for heat transfer by vertical ground heat exchangers (GHEs): a perspective of time and space scales, Appl. Energy 151 (2015) 178–191.

7 E.Atam, L. Helsen, Ground-coupled heat pumps: part 1 –Literature review and research challenges in modeling and optimal control, Renew. Sustain. Energy Rev. 54 (2016) 1653– 1667.

8 N. Zhu, P. Hu, L. Xu, et al., Recent research and applications of ground source heat pump integrated with thermal energy storage systems: a review, Appl. Therm. Eng. 71 (1) (2014) 142–151.

9 S.K. Soni, M. Pandey, V.N. Bartaria, Hybrid ground coupled heat exchanger systems for space heating/cooling applications: a review, Renew. Sustain. Energy Rev. 60 (2016) 724–738.

10 G. Nouri, Y. Noorollahi, H. Yousefi, Solar assisted ground source heat pump systems a review, Appl. Therm. Eng. 163 (2019) 114351.

11 S.K. Shah, L. Aye, B. Rismanchi, Seasonal thermal energy storage system for cold climate zones: a review of recent developments, Renew. Sustain. Energy Rev. 97 (2018) 38–49.

12 I. Tomac, M. Sauter, A review on challenges in the assessment of geomechanical

13 rock performance for deep geothermal reservoir development, Renew. Sustain. Energy Rev. 82 (2018) 3972–3980

14 M.R.A. Sapinska-Sliwa, A. Gonet, et al., Deep borehole heat exchangers - a conceptual and comparative review, Int. J. Air Cond. Refrig. 24 (1) (2016).

15 H. Zeng, N. Diao, Z. Fang, A finite line-source model for boreholes in geothermal heat exchangers, Heat Transf. Asian Res. 31 (7) (2002) 558–567.

16 L.R. Ingersoll, H.J. Plass, Theory of ground pipe heat source for the heat pump, Heat. Pip. Air Cond. 20 (1948) 4.

17 P. Eskilson, Superposition borehole model, Manual for Computer Code, University of Lund, Lund, Sweden, 1986.

18 J. Luo, J. Rohn, W. Xiang, et al., A review of ground investigations for ground source heat pump (GSHP) systems, Energy Build. 117 (2016) 160–175.

19 S.L. Abdelaziz, T.Y. Ozudogru, C.G. Olgun, et al., Multilayer finite line source model [20] for vertical heat exchangers, Geothermics 51 (2014) 406–416.

20 A. Pan, J.S. McCartney, L. Lu, et al., A novel analytical multilayer cylindrical heat source model for vertical ground heat exchangers installed in layered ground, Energy 200 (2020).

21 Z. Zhao, Y.F. Lin, A. Stumpf, et al., Assessing impacts of groundwater on geothermal heat exchangers: a review of methodology and modeling, Renew. Energy 190 (2022) 121–147.

22 N. Diao, Q. Li, Z. Fang, Heat transfer in ground heat exchangers with groundwater advection, Int. J. Therm. Sci. 43 (12) (2004) 1203–1211.

23 M.G. Sutton, D.W. Nutter, R.J. Couvillion, A ground resistance for vertical bore heat exchangers with groundwater flow, J. Energy Resour. Technol. 125 (3) (2003) 183–189.

24 N. Molina-Giraldo, P. Blum, K. Zhu, et al., A moving finite line source model to simulate borehole heat exchangers with groundwater advection, Int. J. Therm. Sci. 50 (12) (2011) 2506– 2513.

25 J. Hu, An improved analytical model for vertical borehole ground heat exchanger with multiplelayer substrates and groundwater flow, Appl. Energy 202 (2017) 537–549.

26 S. Erol, B. Franзois, Multilayer analytical model for vertical ground heat exchanger with groundwater flow, Geothermics 71 (2018) 294–305

27 W. Zhang, H. Yang, N. Diao, et al., Exploration on the reverse calculation method of groundwater velocity by means of the moving line heat source, Int. J. Therm. of vertical water flow, Renew. Energy 172 (2021) 1046–1062.

28 A. Pan, L. Lu, Y. Tian, A new analytical model for short vertical ground heat exchangers with Neumann and Robin boundary conditions on ground surface, Int. J. Therm. Sci. (2020) 152.

29 G. Hellstrцm, Ground heat storage:thermal analysis of duct storage system, in: Physics & Astronomy, Unversity of Lund, Lund, Sweden, 1991, p. 262.

30 S.A. Klein, et al., TRNSYS Manual, A Transient Simulation Program, Solar Engineering Laboratory. University of Wisconsin-Madison, Madison, 1996.

31 I.I. Stylianou, S. Tassou, P. Christodoulides, et al., Modeling of vertical ground heat exchangers in the presence of groundwater flow and underground temperature gradient, Energy Build. 192 (2019) 15–30.

32 K. Chen, J. Zheng, J. Li, et al., Numerical study on the heat performance of enhanced coaxial borehole heat exchanger and double U borehole heat exchanger, Appl. Therm. Eng. 203 (2022) 117916

33 M. Chwieduk, New global thermal numerical model of vertical U-tube ground heat exchanger, Renew. Energy 168 (2021) 343–352.

34 G. Li, J. Yang, X. Zhu, et al., Numerical study on the heat transfer performance of coaxial shallow borehole heat exchanger, Energy Built Environ. 2 (4) (2021) 445–455.

35 P. Eskilson, J. Claesson, Thermal Analysis of Heat Extraction Boreholes, University of Lund, 1987 PhD Doctoral Thesis.

36 P. Eskilson, J. Claesson, Simulation model for thermally interacting heat extraction boreholes, Numer. Heat Transf. 13 (2) (1988) 149–165.

37 J. Claesson, P. Eskilson, Thermal analysis of heat extraction boreholes, in: Proceedings of the 3rd International Conference on Energy Storage for Building Heating and Cooling ENERSTOCK 85, Toronto (Canada), Public Works, 1985,pp. 222–227. September 22-26.

38 . Yavuzturk, J.D. Spitler, A short time step response factor model for vertical ground loop heat exchangers, ASHRAE Trans. 105 (2) (1999) 475–485.

39 C. Prieto, M. Cimmino, Thermal interactions in large irregular fields of geothermal boreholes: the method of equivalent boreholes, J. Build. Perform. Simul. 14 (4) (2021) 446–460.

40 M. Cimmino, Semi-analytical method for g-function calculation of bore fields with series and parallel-connected boreholes, Sci. Technol. Built Environ. 25 (8) (2019) 1007–1022.

41 ] M. Li, A.C.K. Lai, Analytical model for short-time responses of ground heat exchangers with U-shaped tubes: model development and validation, Appl. Energy 104 (2013) 510–516.

42 A. Zarrella, M. Scarpa, M. De Carli, Short time step analysis of vertical groundcoupled heat exchangers: the approach of CaRM, Renew. Energy 36 (9) (2011)2357–2367.

43 [44J. Wei, L. Wang, L. Jia, et al., A new analytical model for short-time response of vertical ground heat exchangers using equivalent diameter method, Energy Build. 119 (2016) 13–19.

Waiting

№	Author name	position	Name of organisation
1	Xamrayev S.I.	texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent,	Qarshi muhandislik-iqtisodiyot instituti
2	Ibragimov U.X.	texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent,	Qarshi muhandislik-iqtisodiyot instituti

№	Name of reference
1	J.W. Lund, A.N. Toth, Direct utilization of geothermal energy 2020 worldwide review, Geothermics 90 (2021) 101915.
2	Khamraev S.I, Ibragimov U.Kh, Kamolov B.I. Removal of hydrodynamic lesions of a heated floor with a solar collector // APEC-V-2022 IOP Conf. Series: Earth and Environmental Science 1070(2022) 012018 IOP Publishing doi:10.1088/1755-1315/1070/1/012018.
3	Uzakov G. N., Charvinski V. L., Ibragimov U. Kh., Khamraev S.I., Kamolov B. I. (2022) Mathematical Modeling of the Combined Heat Supply System of a Solar House. Energetika. Proc. CIS Higher Educ. Inst. and Power Eng. Assoc. 65 (5), 412–421. https://doi.org/10. 21122/1029-7448-2022-65-5-412-421.
4	Y. Yuan, X. Cao, L. Sun, et al., Ground source heat pump system: a review of simulation in China, Renew. Sustain. Energy Rev. 16 (9) (2012) 6814–6822
5	H. Yang, P. Cui, Z. Fang, Vertical-borehole ground-coupled heat pumps: a review of models and systems, Appl. Energy 87 (1) (2010) 16–27.
6	M. Li, A.C.K. Lai, Review of analytical models for heat transfer by vertical ground heat exchangers (GHEs): a perspective of time and space scales, Appl. Energy 151 (2015) 178–191.
7	E.Atam, L. Helsen, Ground-coupled heat pumps: part 1 –Literature review and research challenges in modeling and optimal control, Renew. Sustain. Energy Rev. 54 (2016) 1653– 1667.
8	N. Zhu, P. Hu, L. Xu, et al., Recent research and applications of ground source heat pump integrated with thermal energy storage systems: a review, Appl. Therm. Eng. 71 (1) (2014) 142–151.
9	S.K. Soni, M. Pandey, V.N. Bartaria, Hybrid ground coupled heat exchanger systems for space heating/cooling applications: a review, Renew. Sustain. Energy Rev. 60 (2016) 724–738.
10	G. Nouri, Y. Noorollahi, H. Yousefi, Solar assisted ground source heat pump systems a review, Appl. Therm. Eng. 163 (2019) 114351.
11	S.K. Shah, L. Aye, B. Rismanchi, Seasonal thermal energy storage system for cold climate zones: a review of recent developments, Renew. Sustain. Energy Rev. 97 (2018) 38–49.
12	I. Tomac, M. Sauter, A review on challenges in the assessment of geomechanical
13	rock performance for deep geothermal reservoir development, Renew. Sustain. Energy Rev. 82 (2018) 3972–3980
14	M.R.A. Sapinska-Sliwa, A. Gonet, et al., Deep borehole heat exchangers - a conceptual and comparative review, Int. J. Air Cond. Refrig. 24 (1) (2016).
15	H. Zeng, N. Diao, Z. Fang, A finite line-source model for boreholes in geothermal heat exchangers, Heat Transf. Asian Res. 31 (7) (2002) 558–567.
16	L.R. Ingersoll, H.J. Plass, Theory of ground pipe heat source for the heat pump, Heat. Pip. Air Cond. 20 (1948) 4.
17	P. Eskilson, Superposition borehole model, Manual for Computer Code, University of Lund, Lund, Sweden, 1986.
18	J. Luo, J. Rohn, W. Xiang, et al., A review of ground investigations for ground source heat pump (GSHP) systems, Energy Build. 117 (2016) 160–175.
19	S.L. Abdelaziz, T.Y. Ozudogru, C.G. Olgun, et al., Multilayer finite line source model [20] for vertical heat exchangers, Geothermics 51 (2014) 406–416.
20	A. Pan, J.S. McCartney, L. Lu, et al., A novel analytical multilayer cylindrical heat source model for vertical ground heat exchangers installed in layered ground, Energy 200 (2020).
21	Z. Zhao, Y.F. Lin, A. Stumpf, et al., Assessing impacts of groundwater on geothermal heat exchangers: a review of methodology and modeling, Renew. Energy 190 (2022) 121–147.
22	N. Diao, Q. Li, Z. Fang, Heat transfer in ground heat exchangers with groundwater advection, Int. J. Therm. Sci. 43 (12) (2004) 1203–1211.
23	M.G. Sutton, D.W. Nutter, R.J. Couvillion, A ground resistance for vertical bore heat exchangers with groundwater flow, J. Energy Resour. Technol. 125 (3) (2003) 183–189.
24	N. Molina-Giraldo, P. Blum, K. Zhu, et al., A moving finite line source model to simulate borehole heat exchangers with groundwater advection, Int. J. Therm. Sci. 50 (12) (2011) 2506– 2513.
25	J. Hu, An improved analytical model for vertical borehole ground heat exchanger with multiplelayer substrates and groundwater flow, Appl. Energy 202 (2017) 537–549.
26	S. Erol, B. Franзois, Multilayer analytical model for vertical ground heat exchanger with groundwater flow, Geothermics 71 (2018) 294–305
27	W. Zhang, H. Yang, N. Diao, et al., Exploration on the reverse calculation method of groundwater velocity by means of the moving line heat source, Int. J. Therm. of vertical water flow, Renew. Energy 172 (2021) 1046–1062.
28	A. Pan, L. Lu, Y. Tian, A new analytical model for short vertical ground heat exchangers with Neumann and Robin boundary conditions on ground surface, Int. J. Therm. Sci. (2020) 152.
29	G. Hellstrцm, Ground heat storage:thermal analysis of duct storage system, in: Physics & Astronomy, Unversity of Lund, Lund, Sweden, 1991, p. 262.
30	S.A. Klein, et al., TRNSYS Manual, A Transient Simulation Program, Solar Engineering Laboratory. University of Wisconsin-Madison, Madison, 1996.
31	I.I. Stylianou, S. Tassou, P. Christodoulides, et al., Modeling of vertical ground heat exchangers in the presence of groundwater flow and underground temperature gradient, Energy Build. 192 (2019) 15–30.
32	K. Chen, J. Zheng, J. Li, et al., Numerical study on the heat performance of enhanced coaxial borehole heat exchanger and double U borehole heat exchanger, Appl. Therm. Eng. 203 (2022) 117916
33	M. Chwieduk, New global thermal numerical model of vertical U-tube ground heat exchanger, Renew. Energy 168 (2021) 343–352.
34	G. Li, J. Yang, X. Zhu, et al., Numerical study on the heat transfer performance of coaxial shallow borehole heat exchanger, Energy Built Environ. 2 (4) (2021) 445–455.
35	P. Eskilson, J. Claesson, Thermal Analysis of Heat Extraction Boreholes, University of Lund, 1987 PhD Doctoral Thesis.
36	P. Eskilson, J. Claesson, Simulation model for thermally interacting heat extraction boreholes, Numer. Heat Transf. 13 (2) (1988) 149–165.
37	J. Claesson, P. Eskilson, Thermal analysis of heat extraction boreholes, in: Proceedings of the 3rd International Conference on Energy Storage for Building Heating and Cooling ENERSTOCK 85, Toronto (Canada), Public Works, 1985,pp. 222–227. September 22-26.
38	. Yavuzturk, J.D. Spitler, A short time step response factor model for vertical ground loop heat exchangers, ASHRAE Trans. 105 (2) (1999) 475–485.
39	C. Prieto, M. Cimmino, Thermal interactions in large irregular fields of geothermal boreholes: the method of equivalent boreholes, J. Build. Perform. Simul. 14 (4) (2021) 446–460.
40	M. Cimmino, Semi-analytical method for g-function calculation of bore fields with series and parallel-connected boreholes, Sci. Technol. Built Environ. 25 (8) (2019) 1007–1022.
41	] M. Li, A.C.K. Lai, Analytical model for short-time responses of ground heat exchangers with U-shaped tubes: model development and validation, Appl. Energy 104 (2013) 510–516.
42	A. Zarrella, M. Scarpa, M. De Carli, Short time step analysis of vertical groundcoupled heat exchangers: the approach of CaRM, Renew. Energy 36 (9) (2011)2357–2367.
43	[44J. Wei, L. Wang, L. Jia, et al., A new analytical model for short-time response of vertical ground heat exchangers using equivalent diameter method, Energy Build. 119 (2016) 13–19.