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Year 2018, Volume: 5 Issue: 4, 321 - 337, 31.12.2018
https://doi.org/10.17350/HJSE19030000111

Abstract

References

  • 1. Mujumdar, A. S. (Ed.). (2014). Handbook of Industrial Drying. CRC press.
  • 2. Chua, K. J., Chou, S. K. (2005). A modular approach to study the performance of a two-stage heat pump system for drying. Applied Thermal Engineering, 25(8), 1363-1379.
  • 3. Liu, X., Lee, D. J. (2015). Some recent research and development in drying technologies: Product perspective. Drying Technology, 33(11), 1339-1349.
  • 4. Sivasakthivel, T., Murugesan, K., Thomas, H. R. (2014). Optimization of operating parameters of ground source heat pump system for space heating and cooling by Taguchi method and utility concept. Applied Energy, 116, 76-85.
  • 5. Zamfirescu, C., Dincer, I., Naterer, G. (2009). Performance evaluation of organic and titanium based working fluids for hightemperature heat pumps. Thermochimica Acta, 496(1), 18-25.
  • 6. Tian, Y., Zhao, Y., Huang, J., Zeng, H., Zheng, B. (2016). Effects of different drying methods on the product quality and volatile compounds of whole shiitake mushrooms. Food Chemistry, 197, 714-722.
  • 7. Kucuk, H., Midilli, A., Kilic, A., Dincer, I. (2014). A review on thinlayer drying-curve equations. Drying Technology, 32(7), 757-773.
  • 8. Erbay, Z., Hepbasli, A. (2014). Application of conventional and advanced exergy analyses to evaluate the performance of a groundsource heat pump (GSHP) dryer used in food drying. Energy Conversion and Management, 78, 499-507.
  • 9. Barzegaravval, H., Dincer, I. (2014). Investigation of Organic Rankine Cycle Performance with Variable Mixture Composition. In Progress in Sustainable Energy Technologies: Generating Renewable Energy (pp. 47-64). Springer International Publishing.
  • 10. Perry, E. J. (1981). Drying by cascade heat pumps. Institute of Refrigeration Management, 18, 1–8.
  • 11. Chua, E. K. J. (2001). Dynamic modelling, experimentation, and optimization of heat pump drying for agricultural products. Drying Technology, 19(3-4), 717-721.
  • 12. Chua, K. J., Chou, S. K., Ho, J. C., Hawlader, M. N. A. (2002). Heat pump drying: Recent developments and future trends. Drying Technology, 20(8), 1579-1610.
  • 13. Li, C. J., Su, C. C. (2003). Experimental study of a series-connected two-evaporator refrigerating system with propane (R-290) as the refrigerant. Applied Thermal Engineering, 23(12), 1503-1514.
  • 14. Dincer, I., Rosen, M. A. (2013). Exergy: Energy, Environment and Sustainable Development. Newnes. Oxford: Elsevier.
  • 15. Gungor, A., Tsatsaronis, G., Gunerhan, H., Hepbasli, A. (2015). Advanced exergoeconomic analysis of a gas engine heat pump (GEHP) for food drying processes. Energy Conversion and Management, 91, 132-139.
  • 16. Erbay, Z., Hepbasli, A. (2014). Application of conventional and advanced exergy analyses to evaluate the performance of a groundsource heat pump (GSHP) dryer used in food drying. Energy Conversion and Management, 78, 499-507.
  • 17. Aktaş, M., Şevik, S., Özdemir, M. B., Gönen, E. (2015). Performance analysis and modeling of a closed-loop heat pump dryer for bay leaves using artificial neural network. Applied Thermal Engineering, 87, 714-723.
  • 18. Chong, C. H., Figiel, A., Law, C. L., Wojdyło, A. (2014). Combined drying of apple cubes by using of heat pump, vacuum-microwave, and intermittent techniques. Food and Bioprocess Technology, 7(4), 975-989.
  • 19. Aktaş, M., Şevik, S., Aktekeli, B. (2016). Development of heat pump and infrared-convective dryer and performance analysis for stale bread drying. Energy Conversion and Management, 113, 82-94.
  • 20. Yang, Z., Zhu, Z., Zhao, F. (2016). Simultaneous control of drying temperature and superheat for a closed-loop heat pump dryer. Applied Thermal Engineering, 93, 571-579.
  • 21. Şevik, S. (2014). Experimental investigation of a new design solarheat pump dryer under the different climatic conditions and drying behavior of selected products. Solar Energy, 105, 190-205.
  • 22. Gao, R., Yuan, L., Yu, M., Liu, W. (2016). Effects of Heat Pump Drying Parameters on the Volatile Flavor Compounds in Silver Carp. Journal of Aquatic Food Product Technology, 25(5), 735-744.
  • 23. Chapchaimoh, K., Poomsa-ad, N., Wiset, L., Morris, J. (2016). Thermal characteristics of heat pump dryer for ginger drying. Applied Thermal Engineering, 95, 491-498.
  • 24. Zhang, R., Gao, Y., Feng, J., Xie, H., Deng, H., Zhuang, G., Dou, Z. (2016). Technologic parameter optimization in pilot-scale process of heat pump drying of Areca catechu L. Transactions of theChinese Society of Agricultural Engineering, 32(9), 241-247.
  • 25. Ceylan, İ., & Gürel, A. E. (2016). Solar-assisted fluidized bed dryer integrated with a heat pump for mint leaves. Applied Thermal Engineering, 106, 899-905.
  • 26. Buker, M. S., Riffat, S. B. (2016). Solar assisted heat pump systems for low temperature water heating applications: A systematic review. Renewable and Sustainable Energy Reviews, 55, 399-413.
  • 27. Erbay, Z., Hepbasli, A. (2014). Advanced exergoeconomic evaluation of a heat pump food dryer. Biosystems Engineering, 124, 29-39.
  • 28. Mohanraj, M. (2014). Performance of a solar-ambient hybrid source heat pump drier for copra drying under hot-humid weather conditions. Energy for Sustainable Development, 23, 165-169.
  • 29. Minea, V. (2015). Overview of heat-pump–assisted drying systems, part I: Integration, control complexity, and applicability of new innovative concepts. Drying Technology, 33(5), 515-526.
  • 30. Bansal, P., Mohabir, A., Miller, W. (2016). A novel method to determine air leakage in heat pump clothes dryers. Energy, 96, 1-7.
  • 31. Mehrpooya, M., Hemmatabady, H., Ahmadi, M. H. (2015). Optimization of performance of combined solar collectorgeothermal heat pump systems to supply thermal load needed for heating greenhouses. Energy Conversion and Management, 97, 382-392.
  • 32. Ahn, J. H., Kang, H., Lee, H. S., Kim, Y. (2015). Performance characteristics of a dual-evaporator heat pump system for effective dehumidifying and heating of a cabin in electric vehicles. Applied Energy, 146, 29-37.
  • 33. Yahya, M. (2016). Design and performance evaluation of a solar assisted heat pump dryer integrated with biomass furnace for red chilli. International Journal of Photoenergy, 2016.
  • 34. Minea, V. (2015). Overview of Heat-Pump–Assisted Drying Systems, Part II: Data Provided vs. Results Reported. Drying Technology, 33(5), 527-540.
  • 35. Trirattanapikul, W., Phoungchandang, S. (2014). Microwave blanching and drying characteristics of Centella asiatica (L.) urban leaves using tray and heat pump-assisted dehumidified drying. Journal of Food Science and Technology, 51(12), 3623-3634.
  • 36. Syahrul, S., Hamdullahpur, F., Dincer, I. (2002). Exergy analysis of fluidized bed drying of moist particles. Exergy, an International Journal, 2(2), 87-98.
  • 37. Dincer, I. (2002). On energetic, exergetic and environmental aspects of drying systems. International Journal of Energy Research, 26(8), 717-727.
  • 38. Dincer, I., Sahin, A. Z. (2004). A new model for thermodynamic analysis of a drying process. International Journal of Heat and Mass Transfer, 47(4), 645-652.
  • 39. Rosen, M. A., Dincer, I. (1997). On exergy and environmental impact. International Journal of Energy Research, 21(7), 643-654.
  • 40. Dincer, I. (2011). Exergy as a potential tool for sustainable drying systems. Sustainable Cities and Society, 1(2), 91-96.
  • 41. Dincer, I. (2016). Smart energy solutions. International Journal of Energy Research, 40(13), 1741-1742.
  • 42. Dincer, I. (2016). Exergization. International Journal of Energy Research, 40(14), 1887-1889.
  • 43. Dincer, I. (2016). Greenization. International Journal of Energy Research, 40(15), 2035-2037.

Energetic and Exergetic Investigations of an Integrated Heat Pump System for Drying Applications

Year 2018, Volume: 5 Issue: 4, 321 - 337, 31.12.2018
https://doi.org/10.17350/HJSE19030000111

Abstract

The main aim of this study is to conduct energetic and exergetic investigations of a dual stage heat pump for drying applications in order to evaluate the performance of the overall system. The integrated system consists of two processes, namely a drying unit and a dual stage heat pump. In the heat pump process, R-134A is used as the thermodynamic fluid and the drying unit is used to reduce the moisture content of the air. There are two evaporators used in the dual stage heat pump process: the first evaporator works at high pressures and the second evaporator works at lower pressures. The second evaporator provides supplementary cooling and drying effect for the air used in the drying unit. In the integrated system, there are two sub-coolers which provide additional heating to R-134A after the condenser. In this study, the energy and exergy efficiencies and exergy destruction rates of the overall integrated system, and each component and subprocess are calculated and discussed in detail. Exergetic performance of each component and subprocess are further investigated to identify where the highest exergy destructions occur in order to minimize irreversibilities within the integrated system and hence enhance the overall exergetic efficiency of the integrated system. The impact of environmental conditions on exergetic efficiency and exergy destruction is investigated via parametric studies. In addition, the coefficient of performance COP of the whole system and the effect of operating conditions are examined. The highest energy and exergy efficiencies occur when the drying unit’s inlet air mass flow rate is 0.5 kg/s and the environmental pressure and temperature are at 101 kPa and 298K which are 62% and 35%, respectively. The overall integrated system has a COP of around 3.8.

References

  • 1. Mujumdar, A. S. (Ed.). (2014). Handbook of Industrial Drying. CRC press.
  • 2. Chua, K. J., Chou, S. K. (2005). A modular approach to study the performance of a two-stage heat pump system for drying. Applied Thermal Engineering, 25(8), 1363-1379.
  • 3. Liu, X., Lee, D. J. (2015). Some recent research and development in drying technologies: Product perspective. Drying Technology, 33(11), 1339-1349.
  • 4. Sivasakthivel, T., Murugesan, K., Thomas, H. R. (2014). Optimization of operating parameters of ground source heat pump system for space heating and cooling by Taguchi method and utility concept. Applied Energy, 116, 76-85.
  • 5. Zamfirescu, C., Dincer, I., Naterer, G. (2009). Performance evaluation of organic and titanium based working fluids for hightemperature heat pumps. Thermochimica Acta, 496(1), 18-25.
  • 6. Tian, Y., Zhao, Y., Huang, J., Zeng, H., Zheng, B. (2016). Effects of different drying methods on the product quality and volatile compounds of whole shiitake mushrooms. Food Chemistry, 197, 714-722.
  • 7. Kucuk, H., Midilli, A., Kilic, A., Dincer, I. (2014). A review on thinlayer drying-curve equations. Drying Technology, 32(7), 757-773.
  • 8. Erbay, Z., Hepbasli, A. (2014). Application of conventional and advanced exergy analyses to evaluate the performance of a groundsource heat pump (GSHP) dryer used in food drying. Energy Conversion and Management, 78, 499-507.
  • 9. Barzegaravval, H., Dincer, I. (2014). Investigation of Organic Rankine Cycle Performance with Variable Mixture Composition. In Progress in Sustainable Energy Technologies: Generating Renewable Energy (pp. 47-64). Springer International Publishing.
  • 10. Perry, E. J. (1981). Drying by cascade heat pumps. Institute of Refrigeration Management, 18, 1–8.
  • 11. Chua, E. K. J. (2001). Dynamic modelling, experimentation, and optimization of heat pump drying for agricultural products. Drying Technology, 19(3-4), 717-721.
  • 12. Chua, K. J., Chou, S. K., Ho, J. C., Hawlader, M. N. A. (2002). Heat pump drying: Recent developments and future trends. Drying Technology, 20(8), 1579-1610.
  • 13. Li, C. J., Su, C. C. (2003). Experimental study of a series-connected two-evaporator refrigerating system with propane (R-290) as the refrigerant. Applied Thermal Engineering, 23(12), 1503-1514.
  • 14. Dincer, I., Rosen, M. A. (2013). Exergy: Energy, Environment and Sustainable Development. Newnes. Oxford: Elsevier.
  • 15. Gungor, A., Tsatsaronis, G., Gunerhan, H., Hepbasli, A. (2015). Advanced exergoeconomic analysis of a gas engine heat pump (GEHP) for food drying processes. Energy Conversion and Management, 91, 132-139.
  • 16. Erbay, Z., Hepbasli, A. (2014). Application of conventional and advanced exergy analyses to evaluate the performance of a groundsource heat pump (GSHP) dryer used in food drying. Energy Conversion and Management, 78, 499-507.
  • 17. Aktaş, M., Şevik, S., Özdemir, M. B., Gönen, E. (2015). Performance analysis and modeling of a closed-loop heat pump dryer for bay leaves using artificial neural network. Applied Thermal Engineering, 87, 714-723.
  • 18. Chong, C. H., Figiel, A., Law, C. L., Wojdyło, A. (2014). Combined drying of apple cubes by using of heat pump, vacuum-microwave, and intermittent techniques. Food and Bioprocess Technology, 7(4), 975-989.
  • 19. Aktaş, M., Şevik, S., Aktekeli, B. (2016). Development of heat pump and infrared-convective dryer and performance analysis for stale bread drying. Energy Conversion and Management, 113, 82-94.
  • 20. Yang, Z., Zhu, Z., Zhao, F. (2016). Simultaneous control of drying temperature and superheat for a closed-loop heat pump dryer. Applied Thermal Engineering, 93, 571-579.
  • 21. Şevik, S. (2014). Experimental investigation of a new design solarheat pump dryer under the different climatic conditions and drying behavior of selected products. Solar Energy, 105, 190-205.
  • 22. Gao, R., Yuan, L., Yu, M., Liu, W. (2016). Effects of Heat Pump Drying Parameters on the Volatile Flavor Compounds in Silver Carp. Journal of Aquatic Food Product Technology, 25(5), 735-744.
  • 23. Chapchaimoh, K., Poomsa-ad, N., Wiset, L., Morris, J. (2016). Thermal characteristics of heat pump dryer for ginger drying. Applied Thermal Engineering, 95, 491-498.
  • 24. Zhang, R., Gao, Y., Feng, J., Xie, H., Deng, H., Zhuang, G., Dou, Z. (2016). Technologic parameter optimization in pilot-scale process of heat pump drying of Areca catechu L. Transactions of theChinese Society of Agricultural Engineering, 32(9), 241-247.
  • 25. Ceylan, İ., & Gürel, A. E. (2016). Solar-assisted fluidized bed dryer integrated with a heat pump for mint leaves. Applied Thermal Engineering, 106, 899-905.
  • 26. Buker, M. S., Riffat, S. B. (2016). Solar assisted heat pump systems for low temperature water heating applications: A systematic review. Renewable and Sustainable Energy Reviews, 55, 399-413.
  • 27. Erbay, Z., Hepbasli, A. (2014). Advanced exergoeconomic evaluation of a heat pump food dryer. Biosystems Engineering, 124, 29-39.
  • 28. Mohanraj, M. (2014). Performance of a solar-ambient hybrid source heat pump drier for copra drying under hot-humid weather conditions. Energy for Sustainable Development, 23, 165-169.
  • 29. Minea, V. (2015). Overview of heat-pump–assisted drying systems, part I: Integration, control complexity, and applicability of new innovative concepts. Drying Technology, 33(5), 515-526.
  • 30. Bansal, P., Mohabir, A., Miller, W. (2016). A novel method to determine air leakage in heat pump clothes dryers. Energy, 96, 1-7.
  • 31. Mehrpooya, M., Hemmatabady, H., Ahmadi, M. H. (2015). Optimization of performance of combined solar collectorgeothermal heat pump systems to supply thermal load needed for heating greenhouses. Energy Conversion and Management, 97, 382-392.
  • 32. Ahn, J. H., Kang, H., Lee, H. S., Kim, Y. (2015). Performance characteristics of a dual-evaporator heat pump system for effective dehumidifying and heating of a cabin in electric vehicles. Applied Energy, 146, 29-37.
  • 33. Yahya, M. (2016). Design and performance evaluation of a solar assisted heat pump dryer integrated with biomass furnace for red chilli. International Journal of Photoenergy, 2016.
  • 34. Minea, V. (2015). Overview of Heat-Pump–Assisted Drying Systems, Part II: Data Provided vs. Results Reported. Drying Technology, 33(5), 527-540.
  • 35. Trirattanapikul, W., Phoungchandang, S. (2014). Microwave blanching and drying characteristics of Centella asiatica (L.) urban leaves using tray and heat pump-assisted dehumidified drying. Journal of Food Science and Technology, 51(12), 3623-3634.
  • 36. Syahrul, S., Hamdullahpur, F., Dincer, I. (2002). Exergy analysis of fluidized bed drying of moist particles. Exergy, an International Journal, 2(2), 87-98.
  • 37. Dincer, I. (2002). On energetic, exergetic and environmental aspects of drying systems. International Journal of Energy Research, 26(8), 717-727.
  • 38. Dincer, I., Sahin, A. Z. (2004). A new model for thermodynamic analysis of a drying process. International Journal of Heat and Mass Transfer, 47(4), 645-652.
  • 39. Rosen, M. A., Dincer, I. (1997). On exergy and environmental impact. International Journal of Energy Research, 21(7), 643-654.
  • 40. Dincer, I. (2011). Exergy as a potential tool for sustainable drying systems. Sustainable Cities and Society, 1(2), 91-96.
  • 41. Dincer, I. (2016). Smart energy solutions. International Journal of Energy Research, 40(13), 1741-1742.
  • 42. Dincer, I. (2016). Exergization. International Journal of Energy Research, 40(14), 1887-1889.
  • 43. Dincer, I. (2016). Greenization. International Journal of Energy Research, 40(15), 2035-2037.
There are 43 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Canan Acar This is me

Publication Date December 31, 2018
Published in Issue Year 2018 Volume: 5 Issue: 4

Cite

Vancouver Acar C. Energetic and Exergetic Investigations of an Integrated Heat Pump System for Drying Applications. Hittite J Sci Eng. 2018;5(4):321-37.

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