Sage Journals: Discover world-class research

Abstract

The benefits of thermal energy storage using phase change materials are well documented in the literature. Despite all the potential benefits of thermal energy storage, its commercial and widespread application remains limited. This is due to the high initial cost of phase change materials, extensive rework required in buildings, major modifications in HVAC systems, and the potential for leakage, fire and toxicity hazards. There is a strong need for a simple thermal energy storage solution which can be adopted by large number of consumers. Ductless split air-conditioners are portable, low cost, efficient and account for 70% of all air-conditioning systems sold worldwide each year. The present research provides a novel and low cost solution that incorporates thermal energy storage in these air conditioners, allowing them to run without electricity for 3 h. The paper deals with the detailed design aspects and engineering challenges that arise when incorporating thermal energy storage in these small units. A prototype air-conditioner with in-built thermal energy storage was developed, and all performance parameters presented have been validated through data obtained from the prototype. Our results indicate that thermal energy storage can be incorporated in split units in low cost and with minimal drop in overall energy efficiency of the system.

Practical application: Incorporating thermal energy storage in split air-conditioners which enables them to run without grid for many hours has immense practical applications. Since around 50% power in any building is consumed by HVAC systems, being able to provide cooling during peak hours without using grid can significantly reduce load on the grid without compromising user comfort. For developing countries where load shedding is frequent, the users can run these air-conditioners without the use of generators or batteries thus saving costs and the environment.

Keywords

Phase change materials thermal energy storage ice thermal storage split air-conditioner

Get full access to this article

View all access options for this article.

References

Tyagi

Buddhi

. PCM thermal storage in buildings: a state of art. Renew Sustain Energy Rev 2007; 11: 1146–1166.

Sharma

Tyagi

Chen

, et al. Review on thermal energy storage with phase change materials and applications. Renew Sustain energy Rev 2009; 13: 318–345.

Mohamed

Al-Sulaiman

Ibrahim

, et al. A review on current status and challenges of inorganic phase change materials for thermal energy storage systems. Renew Sustain Energy Rev 2017; 70: 1072–1089.

Souayfane

Fardoun

Biwole

P-H

. Phase change materials (PCM) for cooling applications in buildings: a review. Energy Build 2016; 129: 396–431.

Hwang

Radermacher

. Review of cold storage materials for air conditioning application. Int J Refrig 2012; 35: 2053–2077.

Al-Abidi

Mat

S Bin

Sopian

, et al. Review of thermal energy storage for air conditioning systems. Renew Sustain energy Rev 2012; 16: 5802–5819.

Muthuvel

Saravanasankar

Sudhakarapandian

, et al. Passive cooling by phase change material usage in construction. Build Serv Eng Res Technol 2015; 36: 411–421.

Ozdenefe

Dewsbury

. Thermal performance of a typical residential Cyprus building with phase change materials. Build Serv Eng Res Technol 2015; 37: 85–102.

Ramakrishnan

Wang

Sanjayan

, et al. Thermal performance of buildings integrated with phase change materials to reduce heat stress risks during extreme heatwave events. Appl Energy 2017; 194: 410–421.

10.

Bastien

Athienitis

. Passive thermal energy storage, part 1: design concepts and metrics. Renew Energy 2018; 115: 1319–1327.

11.

Cui

Tang

Qin

, et al. Development of structural-functional integrated energy storage concrete with innovative macro-encapsulated PCM by hollow steel ball. Appl Energy 2017; 185: 107–118.

12.

Lin

Yuan

, et al. Experimental and numerical investigations on the thermal performance of building plane containing CaCl₂·6H₂O/expanded graphite composite phase change material. Appl Energy 2017; 193: 325–335.

13.

Comodi

Carducci

Sze

, et al. Storing energy for cooling demand management in tropical climates: a techno-economic comparison between different energy storage technologies. Energy 2017; 121: 676–694.

14.

M-T

Weng

K-L

Chiang

C-M

. Performance evaluation of an innovative fan-coil unit: low-temperature differential variable air volume FCU. Energy Build 2007; 39: 702–708.

15.

Aneke

Wang

. Energy storage technologies and real life applications – a state of the art review. Appl Energy 2016; 179: 350–377.

16.

Wang

Kusumoto

. Ice slurry based thermal storage in multifunctional buildings. Heat Mass Transf 2001; 37: 597–604.

17.

Arcuri

Spataru

Barrett

. Evaluation of ice thermal energy storage (ITES) for commercial buildings in cities in Brazil. Sustain Cities Soc 2017; 29: 178–192.

18.

Lawrence

Meier

Martinez

. Energy use of icemaking in domestic refrigerators. ASHRAE Transactions 1996; 102(2): 1071–1076.

19.

Wang

, et al. The performance of two adsorption ice making test units using activated carbon and a carbon composite as adsorbents. Carbon N Y 2006; 44: 2671–2680.

20.

Boubakri

Guilleminot

Meunier

. Adsorptive solar powered ice maker: experiments and model. Sol Energy 2000; 69: 249–263.

21.

Afram

Janabi-Sharifi

. Effects of dead-band and set-point settings of on/off controllers on the energy consumption and equipment switching frequency of a residential HVAC system. J Process Control 2016; 47: 161–174.

22.

Jamil

. On the electricity shortage, price and electricity theft nexus. Energy Policy 2013; 54: 267–272.

23.

Sundhar

. Direct current mini air conditioning system, Google Patents, 2002.

24.

Ahmad

Saqib

Kashif

SAR

, et al. Impact of wide-spread use of uninterruptible power supplies on Pakistan’s power system. Energy Policy 2016; 98: 629–636.

25.

Kim

Choi

Chunh

, et al. Experimental study on the performance of multi-split heat pump system with thermal energy storage. Int J Refrig 2018. http://linkinghub.elsevier.com/retrieve/pii/S0140700718300811 .

26.

Jannesari

Abdollahi

. Experimental and numerical study of thin ring and annular fin effects on improving the ice formation in ice-on-coil thermal storage systems. Appl Energy 2017; 189: 369–384.

27.

Habeebullah

. Economic feasibility of thermal energy storage systems. Energy Build 2007; 39: 355–363.

28.

De Falco

Capocelli

Giannattasio

. Performance analysis of an innovative PCM-based device for cold storage in the civil air conditioning. Energy Build 2016; 122: 1–10.

29.

Rahdar

Emamzadeh

Ataei

. A comparative study on PCM and ice thermal energy storage tank for air-conditioning systems in office buildings. Appl Therm Eng 2016; 96: 391–399.

30.

Rahdar

Heidari

Ataei

, et al. Modeling and optimization of R-717 and R-134a ice thermal energy storage air conditioning systems using NSGA-II and MOPSO algorithms. Appl Therm Eng 2016; 96: 217–227.

31.

C-C

Tsai

S-H

Lin

B-S

. Ice storage air-conditioning system simulation with dynamic electricity pricing: a demand response study. Energies 2016; 9: 113–113.

32.

Huang J-A, Ha T-T and Zhang Y-J. An optimal control method of ice-storage air conditioning based on reducing direct cooling cost sequentially. In: IEEE international conference on power and renewable energy (ICPRE). IEEE; 2016, pp.264–268.

33.

Mohlman

. Air conditioning with ice-brine slurry, Google Patents, 1966.

34.

Rutkowski

. Manual J-residential load calculation: full, Arlington, VA: Air-conditioning Contractors of America, 2004.

35.

Air conditioning clinic. 2011, www.tranebelgium.com/files/book-doc/20/en/20.aqerykdx.pdf.

36.

Abdulgalil

Kosi

Musbah

, et al. Effect of thermal energy storage in energy consumption required for air conditioning system in office building under the African Mediterranean climate. Therm Sci 2014; 18(Suppl. 1): 201–212.

37.

Prasad

BGS

. Effect of liquid on a reciprocating compressor. J Energy Resour Technol 2002; 124: 187–190.

38.

Murray

Lower

Dunham

, et al. Refrigeration system analyzer, Google Patents, 1989.

39.

Scaringe

. Simplified subcooling or superheated indicator and method for air conditioning and other refrigeration systems, Google Patents, 2001.

40.

Gonçalves

Melo

Hermes

CJL

, et al. Experimental mapping of the thermodynamic losses in vapor compression refrigeration systems. J Brazilian Soc Mech Sci Eng 2011; 33: 159–165.

41.

Yang

Liu

. Experimental study on ice slurry refrigeration system with pre-cooling heat exchanger. Engineering 2015; 7: 230–230.

Performance evaluation and design considerations for a split air-conditioner with built-in thermal energy storage

Abstract

Keywords

Get full access to this article

References