Basic Operating Characteristics of CO2 Refrigeration Cycles With Expander-Compressor Unit

Purdue University Purdue e-pubs International Refrigeration and Air Conditioning Conference School of Mechanical Engineering 2006 Basic Operating Characteristics of CO2 Refrigeration Cycles With Expander-Compressor Unit Hirokatsu Kohsokabe Hitachi Ltd. Sunao Funakoshi Hitachi Ltd. Kenji Tojo Hitachi Ltd. Susumu Nakayama Hitachi Ltd. Kyoji Kohno Hitachi Ltd. See next page for additional authors Follow this and additional works at: http://docs.lib.purdue.edu/iracc Kohsokabe, Hirokatsu; Funakoshi, Sunao; Tojo, Kenji; Nakayama, Susumu; Kohno, Kyoji; and Kurashige, Kazutaka, "Basic Operating Characteristics of CO2 Refrigeration Cycles With Expander-Compressor Unit" (2006). International Refrigeration and Air Conditioning Conference. Paper 789. http://docs.lib.purdue.edu/iracc/789 This document has been made available through Purdue e-pubs, a service of the Purdue University Libraries. Please contact epubs@purdue.edu for additional information. Complete proceedings may be acquired in print and on CD-ROM directly from the Ray W. Herrick Laboratories at https://engineering.purdue.edu/ Herrick/Events/orderlit.html

Authors Hirokatsu Kohsokabe, Sunao Funakoshi, Kenji Tojo, Susumu Nakayama, Kyoji Kohno, and Kazutaka Kurashige This article is available at Purdue e-pubs: http://docs.lib.purdue.edu/iracc/789

R159, Page 1 BASIC OPERATING CHARACTERISTICS OF CO 2 REFRIGERATION CYCLES WITH EXPANDER-COMPRESSOR UNIT Hirokatsu Kohsokabe 1, Sunao Funakoshi 2, Kenji Tojo 3, Susumu Nakayama 3, Kyoji Kohno 3, Kazutaka Kurashige 4 1 Hitachi, Ltd., Mechanical Engineering Research Laboratory, 832-2, Horiguchi, Hitachinaka-shi, Ibaraki 312-0034, Japan (Fax: 81(29) 353-3869, E-mail: hirokatsu.kosokabe.mx@hitachi.com) 2 Hitachi, Ltd., Advanced Research Laboratory, 2520 Hatoyama, Saitama 350-0395, Japan 3 Hitachi Appliances, Inc., Air Conditioning Systems Division, 390 Muramatsu, Shimizu-ku Shizuoka-shi 424-0926, Japan 4 Tokyo Electric Power Company, R&D Center, 4-1 Egasaki-cho, Tsurumi-ku, Yokohama 230-8510, Japan ABSTRACT A transcritical CO 2 refrigeration cycle with an expander was studied to improve the coefficient of performance (COP) of the cycle of a simple expansion valve by recovering the throttling loss. We developed an expandercompressor unit. A scroll type expander and a rolling-piston type rotary sub-compressor were adopted and connected them with a shaft. With this unit, we made a CO 2 refrigeration cycle for a small capacity air-cooled chiller and investigated the basic operating characteristics of the cycle. In experiments, the expander-compressor unit was shown to be stable and to improve the COP of the CO 2 chiller cycle under both cooling and heating conditions. The test results indicated that the COP improvement of the cycle was more than 30%, while the total efficiency of the expander-compressor unit was 57%. Expander-compressor unit are a key technology for use in CO 2 refrigeration systems. 1. INTRODUCTION Recently, natural refrigerants have been receiving attention due to global environmental problems. Carbon dioxide (CO 2 ), a natural refrigerant, is a potential substitute for hydrofluorocarbons (HFCs) because of its incombustibility, non-toxicity and low global warming potential (GWP). The coefficient of performance (COP) of CO 2 refrigeration cycles, however, is typically low compared to the HFC refrigeration cycles. The main reason for this low COP is large throttling loss that results from a transcritical refrigeration cycle. Many researchers have been trying to improve the COP of transcritical CO 2 refrigeration cycles. The throttling loss can be reduced by replacing the expansion valve with a work output expansion device (expander or ejector). Various types of expanders have been studied to recover the throttling loss of the CO 2 refrigeration cycles. For example, Nickl et al. (2005) developed a third generation CO 2 reciprocating expander, which has three independent expansion stages. Hays and Brasz (2004) analyzed a transcritical turbine-compressor for CO 2 refrigeration and heat pump systems. Westphalen and Dieckmann (2004) analyzed a scroll expander for CO 2 refrigerant-cooling systems. Similar research is going on in many other companies and universities with different types of expander designs. However, the amount of research for operating characteristics of the CO 2 refrigeration cycle with expanders is relatively small. Fukuta et al. (2001) studied the theoretical performance of the CO 2 cycle with a vane compressor-expander combination. Taking account of the loss due to miss-matching of the operating condition, the theoretical COP of the cycle with the expander was found to be approximately 1.5 times larger than the cycle without the expander. Hiwata et al. (2003) investigated the theoretical performance of the cycle with the expander for both cooling and heating operations. A new refrigeration cycle (change over cycle) was proposed as a cycle with an expander for CO 2 airconditioning systems. This paper shows the experimental performance of a transcritical CO 2 refrigeration cycle with an expandercompressor unit and presents its operating characteristics for both cooling and heating conditions.

R159, Page 2 2. CO 2 REFRIGERATION CYCLE WITH EXPANDER-COMPRESSOR UNIT A CO 2 refrigeration cycle with an expander-compressor unit is shown in Figure 1. This cycle is for an air-cooled heat pump chiller. The specifications of the cycle components are shown in Table 1. The refrigeration cycle consists of a main compressor (MC), an oil separator, a four-way valve, an air-side heat exchanger, an expander-compressor unit, a water/refrigerant heat exchanger, check valves, and etc. The expander-compressor unit includes an expander (EX) and a sub-compressor (SC). In Figure 1, a solid arrow shows the flow of the refrigerant during cooling operation and a broken arrow shows the flow during heating operation. The four-way valve changes these two operating modes. In both cooling and heating operation, check valves fix the flow direction of the refrigerant to the expander so that the expander always recovers the energy. This recovered energy directly drives the sub-compressor. Here, the sub-compressor acts as a boosted compressor and reduces the power of the main compressor. Figure 2 shows an ideal P-h diagram of the CO 2 cycle with the expander-compressor unit. An expansion process and a compression process are assumed to be isentropic. The line from point A to B indicates the compression process of the sub-compressor, and the line from point B to C indicates the compression process of the main-compressor. The line from point D to E indicates the expansion process of the expander. The total efficiency of the expandercompressor unit η t is defined by η t =Δh sc /Δh ex (1) whereδh sc is the isentropic enthalpy difference of the sub-compressor, and Δh ex is the isentropic enthalpy difference of the expander. In Figure 2, the evaporating temperature T e is, the suction super-heat degree is 0, the heat rejection pressure P h is 9.0MPa and the expander inlet temperature T i is 36. The theoretical COP improvement of the cycle with the expander-compressor unit is shown in Figure 3. It can be seen that for the given conditions, the cycle with the expander-compressor unit has a 30% improvement in COP over the basic transcritical CO 2 cycle, while the total efficiency of the expander-compressor unit η t is 50%. 3. EXPANDER-COMPRESSOR UNIT Figure 4 shows a sectional view of the expander-compressor unit (ECU). We used a scroll type expander and a rolling-piston type rotary sub-compressor. Both elements were connected with a crankshaft, so both rotate at the same speed. The ECU design condition is a cooling rated condition. The ECU is lubricated by polyalkylene glycol (PAG) oil, which is stored in the bottom of the casing. The end of the crankshaft is under the oil. The oil pick up supplies the oil to the axial bore of the crankshaft and then feeds it to bearings and other sliding surfaces. The oil separator supplies oil to the casing oil sump (see Figure 1). 4. EXPERIMENT The test conditions are shown in Table 2. The experiments were carried out at different refrigerant charges, ambient temperatures, and water inlet temperatures for both cooling and heating conditions. The performance of the CO 2 cycle with the ECU was compared with the performance of the CO 2 cycle without the ECU (with expansion valve). In one testing cycle, the temperature and pressure at each component, the refrigerant mass flow rate, the compressor power input, and the rotating speed of the ECU were measured. The system capacity calculated to the amount of heat exchange from the water side. The cooing or heating capacity Q is given as Q = ρ w C w V w ΔT (2) where ρ w is the water density, C w is the heat capacity of water, V w is the volume flow rate of water, andδt is the average temperature difference between the inlet and outlet water of the water/refrigerant heat exchanger. The COP is the ratio of the cooling or heating capacity to the compressor power input, which is defined by where W i is the compressor power input. COP = Q/W i (3)

R159, Page 3 In experiments, the ECU was stable under both cooling and heating conditions. 5. TEST RESULTS 5.1 Effects of refrigerant charge Figure 5 shows the effects of the refrigerant charge on system performance. Figure 5(a) is a cooling rated condition and Figure 5(b) is a heating rated condition. The relative COP, the system capacity, and the compressor power input were charted. In Figure 5(a), overall, when the refrigerant charge increases, the cooling capacity increases, but its rate of increase is gradually saturates. On the other hand, the compressor power input slightly increases, so the COP has a maximum point at a specific refrigerant charge. The optimum refrigerant charge is 6.4 kg with the ECU and 6.7 kg without the ECU. In Figure 5(b), the results of the heating rated condition are similar to but smaller than the refrigerant charge of the cooling rated condition. The optimum refrigerant charge is 3.35 kg with the ECU and 3.6 kg without the ECU. In Figure 5, the CO 2 refrigeration cycle with the ECU improved the COP by more than 30%. 5.2 Effects of inlet water temperature Figure 6-7 shows the effects of inlet water temperature. The refrigerant charge remained at the optimum value. Figure 6 shows the relative COP at the cooling condition. Figure 7 shows the relative COP at the heating condition. The COP with the ECU is above the COP without the ECU. These results indicate that though the ECU was designed for the cooling rated condition, it improves the COP of the cycle under the different operating conditions. Figure 8 shows a P-h diagram of the CO 2 cycle with the ECU at cooling rated condition. In this figure, the line from point A to B indicates the compression process of the ECU, and the line from point D to E indicates the expansion process of the ECU. A two-dot chain line means a constant entropy S. Based on this figure, the results from Equation (1), the total efficiency η t is 57%. 6. CONCLUSIONS We have developed an expander-compressor unit and investigated the basic operating characteristics of the CO 2 refrigeration cycle. As a result, the following conclusions were obtained: The expander-compressor unit improves the COP of the CO 2 chiller cycle under both cooling and heating conditions. The COP improvement of the cycle with the expander-compressor unit was more than 30%, while the total efficiency of the expander-compressor unit was 57%. Expander-compressor unit are a key technology for use in CO 2 refrigeration systems. REFERENCES Nickl, J., et al., 2005, Integration of a three-stage expander into a CO 2 refrigeration systems, Int. J. Refrig., vol. 28, no. 8: p. 1219-1224. Hays, L., Brasz, J.J., 2004, A transcritical CO 2 turbine-compressor, International Compressor Engineering Conference at Purdue, C137. Westphalen, D., Dieckmann, J., 2004, Scroll expander for carbon dioxide air conditioning cycles, International Refrigeration and Air Conditioning Conference at Purdue, R023. Fukuta, M., et al., 2003, Performance prediction of vane type expander for CO 2 -cycle, Proceedings of the 21 st IIR International congress of the refrigeration Washington, ICR251. Kosuda, O., et al., 2005, Performance of scroll expander for CO 2 refrigeration cycle, Proceedings of the 2005 JSARE Annual Conference, C315 (in Japanese). Okamoto, M., et al., 2005, Development of two-phase flow expander for CO 2 air-conditioners, Proceedings of the 2005 JSARE Annual Conference, C316 (in Japanese). Fukuta, M., et al., 2001, Cycle performance of CO 2 cycle with vane compressor-expander combination, IMechE Conf. Trans. of Int. Conf. on Compressors and their Systems, p. 315-324. Hiwata, A., et al., 2003, A study of cycle performance improvement with expander-compressor in air-conditioning systems, IMechE Conf. Trans. of Int. Conf. on Compressors and their Systems, p.339-347.

R159, Page 4 Air-side 空 Heat 気 側 Exchanger 熱 交 換 器 4-way 四 valve 方 弁 Oil オイルセパレータ Separator Check 逆 valve 止 弁 Fan ファン 調 整 弁 Motor モータ Main 主 圧 縮 Compressor 機 EX SC M MC Expander-Compressor 膨 張 / 圧 縮 機 Unit Water/Refrigerant 水 側 熱 交 換 器 Heat Exchanger Load 負 荷 P Pump ポンプ Cooling 冷 却 運 転 Heating 加 熱 運 転 Figure 1: CO 2 air-cooled chiller cycle with expander-compressor unit Table 1: Specifications of CO 2 cycle components Main Compressor Type Motor Scroll AC, 200V, 3.75kW Expander-Compressor Unit Expander Subcompressor Type Type Scroll Rolling-Piston Rotary Air-side Heat Exchanger Type Cross-Fin Tube Water/Refrigerant Heat Exchanger Type Plate and Tube

R159, Page 5 12 S : Entropy Pressure P [MPa] 10 8 6 4 S const. E h ex D 36 T e = A C S const. B h sc 2 250 300 350 400 450 500 Figure 2: P-h diagram of En CO thalpy 2 cycle h with [kj/kg] expander-compressor unit Figure 2: P-h diagram of CO 2 cycle with expander-compressor unit COP 向 上 率 (%) COP Improvement [%] 70 60 50 40 30 20 10 R744 T e = P h = 9.0 MPa T i = 36 0 0 20 40 60 80 100 Total Efficiency 膨 張 / 圧 of 縮 Expander-Compressor 機 の 機 関 効 率 ηt(%) Unit η t [%] Figure 3: COP improvement of CO 2 cycle with expander-compressor unit

R159, Page 6 Casing Scroll Expander Fixed Scroll Orbiting Scroll Balance Weight Crankshaft Rotary Sub-compressor Cylinder Lubricating Oil Roller Oil Pick Up Figure 4: Cross-sectional view of expander-compressor unit Table 2: Test conditions Expansion Device Operating Mode Charge of CO 2 [kg] Ambient Temperature: T a [ ] Water Inlet Temperature: T wi [ ] Expansion Valve Cooling Heating 4.2~7.0 6.7 3.2~4.1 3.6 35 35 7 7 12 9.7~15.9 40 35~45 Expander- Compressor Unit Cooling Heating 4.5~6.4 6.4 2.8~3.45 3.35 35 35 7 7 12 9.7~15.5 40 35~45

R159, Page 7 Relative COP[-] Relative Cooling Capacity[-] Relative Comp. Input[-] 1.6 1.4 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 T a = 35 T wi = 12 V w = 30 l/min 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 (a) Cooling Rated Condition Relative COP[-] Relative Heating Capacity[-] Relative Comp. Input[-] 1.6 1.4 2.5 3.0 3.5 4.0 4.5 2.5 3.0 3.5 4.0 4.5 T a = 7 T wi = 40 V w = 38 l/min 2.5 3.0 3.5 4.0 4.5 (b) Heating Rated Condition Figure 5: Effect of refrigerant charge on performance

R159, Page 8 1.6 1.6 1.4 1.4 Relative COP[-] T a = 35 V w = 30 l/min Relative COP [-] T a = 7 V w = 38 l/min 8 10 12 14 16 18 30 35 40 45 50 Water Inlet Temperature Twi [ ] Water Inlet Temperature Twi [ ] Figure 6: Effect of water inlet temperature on COP (cooling mode) Figure 7: Effect of water inlet temperature on COP (heating mode) 10 D C Pressure P [MPa] 8 6 4 S const. Δh ex E A B Δh sc S const. S: Entropy 2 250 300 350 400 450 500 Enthalpy h [kj/kg] Figure 8: P-h diagram of cooling rated condition