Dynamic model and response characteristics of liquid desiccant air-conditioning system driven by heat pump

Bowen Guan; Xiaohua Liu; Tao Zhang; Andong Wang

doi:10.1007/s12273-021-0789-4

AI Chat Paper

Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.

Chat more with AI

| Sign up

Browse by Subject

Search for peer-reviewed journals with full access.

Journals A - Z

About Us

Discover the SciOpen Platform and Achieve Your Research Goals with Ease.

About Us

Publish with Us

Support

Journals A - Z

About Us

Publish with Us

Support

Article Link

Cite

EndNote(RIS) BibTeX

Collect

Submit Manuscript

Show Outline

Outline

Show full outline

Hide outline

Outline

Show full outline

Hide outline

Research Article

Dynamic model and response characteristics of liquid desiccant air-conditioning system driven by heat pump

Bowen Guan^¹, Xiaohua Liu^¹(

), Tao Zhang^¹, Andong Wang^²

1.Department of Building Science and Technology, Tsinghua University, Beijing 100084, China

2.Department of Electrical and Electronic Engineering, University of Hong Kong, Hong Kong 999077, China

Show Author Information

Abstract

The liquid desiccant air-conditioning system is considered as an energy-efficient alternative to the vapor compression system. The dynamic response characteristics of the system under variable cooling load play an important role in the air temperature and humidity control performance of the system. However, the dynamic response characteristics have not been fully revealed in previous studies. Thus, a dynamic model for a heat pump driven liquid desiccant air-conditioning (HPLDAC) system is established to investigate the dynamic response characteristics of the system in this study. Subsequently, experiments were conducted to validate the accuracy of the dynamic model. The simulation results show a good agreement with the experimental data. The simulation results reveal that evaporating water from the solution is a time-consuming process, compared to adding water to the solution. It spends a long time for the HPLDAC system to decrease the high relative humidity of supply air to a low value, which limits the air temperature and humidity control performance of the system. The upper band for the water replenishing value opening (Δφ_up) is a crucial parameter to improve the limitation. When Δφ_up decreases from 1.0% to 0.25%, the time consumed to reduce the supply air relative humidity to the new lower set value can be saved by 30.6%.

Keywords

dynamic model liquid desiccant response characteristics temperature and humidity independent control air conditioning system

References

Abdel-Salam AH, Simonson CJ (2014). Capacity matching in heat- pump membrane liquid desiccant air conditioning systems. International Journal of Refrigeration, 48: 166-177.

Crossref Google Scholar

Cai D, Qiu C, Zhang J, et al. (2017). Performance analysis of a novel heat pump type air conditioner coupled with a liquid dehumidification/humidification cycle. Energy Conversion and Management, 148: 1291-1305.

Crossref Google Scholar

Dai YJ, Zhang HF (2004). Numerical simulation and theoretical analysis of heat and mass transfer in a cross flow liquid desiccant air dehumidifier packed with honeycomb paper. Energy Conversion and Management, 45: 1343-1356.

Crossref Google Scholar

Ding G, Chen X, Huang Z, et al. (2018). Study on model of household split air conditioning solution dehumidifier. Applied Thermal Engineering, 139: 376-386.

Crossref Google Scholar

Fekadu G, Subudhi S (2018). Renewable energy for liquid desiccants air conditioning system: A review. Renewable and Sustainable Energy Reviews, 93: 364-379.

Crossref Google Scholar

Fujii T, Imura H (1972). Natural-convection heat transfer from a plate with arbitrary inclination. International Journal of Heat and Mass Transfer, 15: 755-767.

Crossref Google Scholar

Giampieri A, Ma Z, Smallbone A, et al. (2018). Thermodynamics and economics of liquid desiccants for heating, ventilation and air-conditioning - An overview. Applied Energy, 220: 455-479.

Crossref Google Scholar

Guan B, Liu X, Zhang T, et al. (2019). Experimental and numerical investigation of a novel hybrid deep-dehumidification system using liquid desiccant. Energy Conversion and Management, 192: 396-411.

Crossref Google Scholar

Huang Z, Luo L, Ke R, et al. (2019). Dehumidification performance experiment of hydrophilic non-woven PVC composite structured packing. CIESC Journal, 70: 913-921. (in Chinese)

Google Scholar

Islam MR, Alan SWL, Chua KJ (2018). Studying the heat and mass transfer process of liquid desiccant for dehumidification and cooling. Applied Energy, 221: 334-347.

Crossref Google Scholar

Kabeel AE, Khalil A, Elsayed SS, et al. (2018). Dynamic behaviour simulation of a liquid desiccant dehumidification system. Energy, 144: 456-471.

Crossref Google Scholar

Liu X, Jiang Y, Xia J, et al. (2007). Analytical solutions of coupled heat and mass transfer processes in liquid desiccant air dehumidifier/ regenerator. Energy Conversion and Management, 48: 2221-2232.

Crossref Google Scholar

Liu X, Li Z, Jiang Y (2009). Similarity of coupled heat and mass transfer between air-water and air-liquid desiccant direct-contact systems. Building and Environment, 44: 2501-2509.

Crossref Google Scholar

Liu J, Zhang T, Liu X, et al. (2015). Experimental analysis of an internally-cooled/heated liquid desiccant dehumidifier/regenerator made of thermally conductive plastic. Energy and Buildings, 99: 75-86.

Crossref Google Scholar

Luo Y, Yang H, Lu L, et al. (2014). A review of the mathematical models for predicting the heat and mass transfer process in the liquid desiccant dehumidifier. Renewable and Sustainable Energy Reviews, 31: 587-599.

Crossref Google Scholar

Mesquita LCS, Harrison SJ, Thomey D (2006). Modeling of heat and mass transfer in parallel plate liquid-desiccant dehumidifiers. Solar Energy, 80: 1475-1482.

Crossref Google Scholar

Qi R, Dong C, Zhang L (2020). A review of liquid desiccant air dehumidification: From system to material manipulations. Energy and Buildings, 215: 109897.

Crossref Google Scholar

Ou X, Cai W, He X, et al. (2018). Dynamic modeling and validation of a liquid desiccant cooling and dehumidification system. Energy and Buildings, 163: 44-57.

Crossref Google Scholar

Sanaye S, Taheri M (2018). Modeling and multi-objective optimization of a modified hybrid liquid desiccant heat pump (LD-HP) system for hot and humid regions. Applied Thermal Engineering, 129: 212-229.

Crossref Google Scholar

Storle D, Abdel-Salam MRH, Simonson CJ (2019). Energy performance comparison of a 3-fluid and 2-fluid liquid desiccant membrane air-conditioning systems in an office building. Energy, 176: 437-456.

Crossref Google Scholar

Sun D, Wang L, Xu J, et al. (2014). Research and application of water tank temperature stratification model for seasonal heat storage. Acta Energiae Solar Sinica, 35: 291-298. (in Chinese)

Google Scholar

Wang L, Xiao F, Niu X, et al. (2017). A dynamic dehumidifier model for simulations and control of liquid desiccant hybrid air conditioning systems. Energy and Buildings, 140: 418-429.

Crossref Google Scholar

Wang X, Wang L, Yin X, et al. (2019). Modeling and performance analyses of a batch-wise liquid desiccant air conditioning system. Building and Environment, 154: 1-12.

Crossref Google Scholar

Wu Q, Cai W, Shen S, et al. (2017). A regulation strategy of working concentration in the dehumidifier of liquid desiccant air conditioner. Applied Energy, 202: 648-661.

Crossref Google Scholar

Yang Z, Qu M, Abdelaziz O, et al. (2019). Development and case study of the liquid desiccant system module in sorption system simulation program (SorpSim). Applied Thermal Engineering, 162: 114261.

Crossref Google Scholar

Yon HR, Cai W, Wang Y, et al. (2018). Dynamic model for a novel liquid desiccant regeneration system operating in vacuum condition. Energy and Buildings, 167: 69-78.

Crossref Google Scholar

Zhang T, Tu R, Liu X (2017). Desiccant air handling processors driven by heat pump. In: Enteria N, Awbi H, Yoshino H (eds), Desiccant Heating, Ventilating, and Air-Conditioning Systems. Singapore: Springer.

Zhang W-K, Yang M, Chen J-C, et al. (2018a). Quasi-counter flow parallel-plate membrane contactors (QCPMC) for liquid desiccant air dehumidification: Conjugate heat and mass transfer. International Journal of Thermal Sciences, 134: 665-672.

Crossref Google Scholar

Zhang F, Yin Y, Zhang X (2018b). Performance analysis of a solar- driven liquid desiccant cooling system with solution storage under adjustable recirculation ratio. Solar Energy, 172: 32-45.

Crossref Google Scholar

Building Simulation

Volume 14 Issue 6,
December 2021

Pages 1773-1784

DOI: 10.1007/s12273-021-0789-4

Cite this article:

Guan B, Liu X, Zhang T, et al. Dynamic model and response characteristics of liquid desiccant air-conditioning system driven by heat pump. Building Simulation, 2021, 14(6): 1773-1784. https://doi.org/10.1007/s12273-021-0789-4

638

Views

Crossref

Web of Science

Scopus

CSCD

Google Scholar
Citation

Altmetrics

Received: 21 November 2020

Revised: 02 February 2021

Accepted: 20 February 2021

Published: 10 March 2021