Available online at www.sciencedirect.com ScienceDirect Procedia Engineering 146 (2016 ) 431 440 8th International Cold Climate HVAC 2015 Conference, CCHVAC 2015 Build and test research of a coaxial hybrid-power gas engine heat pump system based on LiFePO4 battery Wenxiu Ji, Liang Cai*, Qinkun Men, Gaofeng Sun, Xiaosong Zhang 1 School of Energy and Environment, Southeast University, Nanjing 210096, PR China Abstract Power batteries of hybrid-power gas engine heat pump (HPGHP) often encounter frequent charge and discharge operations, which have an adverse effect on nature gas conversion efficiency of system. In order to improve the dynamic efficiency and economic performance of HPGHP, this paper raises a coaxial HPGHP facility, which takes the LiFePO4 battery as the auxiliary power source to drive the compressor. Logic threshold control strategy is put forward to distribute power between the gas engine and battery pack. Test research was operated to verify the advantageous performance of LiFePO4 battery HPGHP. The results show that LiFePO4 battery HPGHP can achieve an obvious energy saving effect, especially in low-load condition and high-load condition. When compressor speed increases from700rpm to 2500rpm, COP decreases from 4.76 to 3.25, heating capacity increases from 14.52 to 33.13kW. The maximum difference of LiFePO4 battery HPGHP and lead-acid battery HPGHP is respectively 13.2%, 11.28% and 10.2% separately for engine thermal efficiency, gas-consumed rate, and energy conversion efficiency under the same load. In addition, reclaimed heat is tested and the result shows that LiFePO4 battery HPGHP is 11.82% lower than conventional nature gas heat pump (GHP). 2016 Published The Authors. by Elsevier Published Ltd. This by Elsevier is an open Ltd. access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of CCHVAC 2015. Peer-review under responsibility of the organizing committee of CCHVAC 2015 Keywords: Hybrid-power; HPGHP; LiFePO4 battery; SOC; gas conversion efficiency 1. Introduction Power battery as an important component of hybrid-power system, its matching and performance has a great influence on power and economy of whole system [1]. In hybrid electric vehicles (HEVs) technology, batteries often encounter instantaneous power demand, thus they tend to perform frequent charge and discharge operations, which * Corresponding author. E-mail address: cailiang@seu.edu.cn 1877-7058 2016 Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of CCHVAC 2015 doi:10.1016/j.proeng.2016.06.425
432 Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 have an adverse effect on battery life and energy conversion efficiency of system [2-3]. Similarly, HPGHP battery is always not fully charged and completely discharged, due to working modes switching used to regulate the frequent variation of external load [4]. According to the usage characteristic mentioned above, special requirements are proposed of HPGHP power battery, which includes high power charge-discharge capacity, high charge-discharge efficiency, and relative stability. Nomenclature N drive demand speed of drive system(rpm) N min minimum speed of engine economic zone(rpm) N max maximum speed of engine economic zone(rpm) T drive demand torque of drive system(nm) T min minimum torque of engine economic zone(nm) T max maximum torque of engine economic zone(nm) SOC low the state of lowest charge of battery SOC high the state of highest charge of battery SOC 1 the state one of charge of battery SOC 2 the state two of charge of battery P the heat transfer (kw) Q c p G r gas consumption (kg h-1) G r equivalent gas consumption (kg h-1) h r f thermal efficiency of gas engine f equivalent thermal efficiency of gas engine d motor efficiency n inverter efficiency g transmission efficiency of gearbox fd transmission efficiency between the engine and motor yg transmission efficiency between the gearbox and compressor dg transmission efficiency between the motor and gearbox fg transmission efficiency between the engine and gearbox ry Energy conversion efficiency 'rc equivalent energy conversion efficiency t H t L P f output power of engine (kw) P y output power of compressor (kw) P d output power of motor(kw) N d speed of motor (rpm) T d torque of motor (N m) P n heat transfer of indoor heat exchanger (kw) P i indicated power of compressor (kw) m mechanical efficiency of the compressor g r gas consumption rate (g (kw h)-1) g r equivalent gas consumption rate (g (kwh)-1) bc battery charging efficiency bf battery discharging efficiency rated capacity of battery Q b
Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 433 Abbreviations LiFePO4 Lithium iron phosphate batteries COP coefficient of performance GHP gas engine heat pump HPGHP hybrid-power gas engine heat pump SOC the state of charge HEVs hybrid electric vehicles Wang and Cai [5] have tested a parallel-type hybrid-power gas engine-driven heat pump system which use leadacid battery as the auxiliary power source to drive the heat pump, which shows that gas-consumed flow changes in 280-340 g (kw h)1 and drive system thermal efficiency is maintained between 0.23 and 0.28 with the increasing compressor speed. Wang et al. [6] have established energy management scheme of lead-acid battery pack. Jiang [7] has built model of lead-acid battery and conclude that the charging efficiency keeps above 0.9 when the charging current value is below 30A, while the average discharge efficiency is higher than 0.93 when the discharging current is less than 50A. Table 1 shows performance comparison of three kinds of batteries mainly used in hybrid cars, which indicates that Lithium-ion battery is the best choice of HPGHP battery, owing to its high energy density, high power density, long cycle life and environmental friendliness. Within the Li-ion battery family, the LiFePO4 type has been considered to be one of the most suitable technologies for high-power automotive applications due to an attractive combination of safety, cycle and calendar life and performance [8-10]. Above all LiFePO4 battery has higher charge-discharge efficiency than lead-acid battery, as is shown in Figure 1. The average charge efficiency and discharge efficiency is respectively 0.968 and 0.971 of LiFePO4 battery, about 13.32% and 3.97% higher than lead-acid battery. Table 1. Battery performance comparison Battery type Specific energy(wh/kg) Energy density(wh/l) Specific power(w/kg) Power density(w/l) Cycle life Lead-acid battery 20~50 65 40~70 120 500~700 NiMH battery 70~80 80~220 100~600 250~800 600~1200 Lithium ion battery 55~150 130~300 300~1500 400 600~1200 For a comprehensive, this paper builds a coaxial hybrid-power gas engine heat pump system which takes LiFePO4 battery as the auxiliary power source to drive the compressor. Logic threshold control strategy which combines the economic zone of the engine with the SOC value of the LiFePO4 battery is adopted in this hybrid-power system. Experiment research is tested to analyze the power efficiency and economic performance of LiFePO4 battery HPGHP system. Advantageous performances of containing LiFePO4 battery technology with HPGHP are especially compared with the previous lead-acid battery HPGHP.
434 Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 0.98 b 0.96 0.94 0.92 0.90 0.88 0.86 charging efficiency of LiFePO4 battery discharging efficiency of LiFePO4 battery charging efficiency of lead-acid battery discharging efficiency of lead-acid battery LiFePO 4 0.84 0.0 0.2 0.4 0.6 0.8 1.0 battery SOC Figure 1. The charging-discharging efficiency curves of Figure 2. Operating principle diagram of HPHP system based on LiFePO4 battery LiFePO4 battery and lead-acid battery at 50A. 2. Build of HPGHP System 2.1. Principle of HPGHP system based on LiFePO4 battery Build of HPGHP system based on LiFePO4 battery is divided into three parts: power-driven system, heat pump system and heat reclaimed system. Figure 2 is the principle diagram of the hybrid-power gas heat pump system based on the LiFePO4 battery. The technical parameters of main devices utilized in the HPGHP system are shown in Table 2. Table 2. Technical parameters of main devices device parameter value Gas engine Motor/generator LiFePO4 battery pack compressor type LJ276M Speed range(rpm) 500-4800 Rated power(kw) 12.5 type PMSM Rated speed(rpm) 3000 Rated power(kw) 6 Rated torque(nm) 20 type AJ-60V100Ah Voltage level(v) 60 Capacity(Ah) 100 Rated current(a) 50 Connection type type 1 parallel, 19 serial Bitzer 4UFRY Volume(L) 0.4 Speed range(rpm) 500-2600 Rated speed(rpm) 1480 refrigerant R134a
Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 435 Ncom Pcom Mode A Engine charges battery N N AMT Ndrive Tdrive SOC>SOClow Y Nmin<Ndrive<Nmax Mode B Motor drives compressor alone N Y Tdrive<Tmin Y SOC<SOChigh Y N N Tdrive<Tmax Y Mode D Engine drives compressor Mode E Engine and motor drive compressor Mode C Engine drives compressor and charges battery Figure 3. The flow chart of logic threshold control strategy Test bed is operated under logic threshold control strategy, which combines the economic zone of the engine with the SOC value of the LiFePO4 battery to achieve the minimum gas consumption. There are five working modes of experimental condition: mode A, engine charges battery; mode B, motor drives compressor alone; mode C, engine drives compressor and charges battery at the same time; mode D, engine drives compressor alone; mode E, engine and motor drive compressor together. Figure 3 shows the flow chart of logic threshold control strategy as well as boundary conditions of each working modes. 3. Test research and data processing of LiFePO4 battery HPGHP 3.1. Calculation of heat transfer Experimental data collected in this test are as follows: inlet and outlet temperature of indoor heat exchanger, outdoor heat exchanger, plate-type heat exchanger and flue gas heat exchanger; volume flow of the pump; evaporating pressure and condensing pressure; motor speed and motor torque, which can be read from PC software; SOC value, current and voltage of the battery, which can be read from battery energy management system. we can get heat transfer of all the heat exchangers using the following formula, PQ c ( t t ) (1) P H L 3.2. Calculation of heat transfer The output power of motor and compressor can be calculated from the following equations, Nd Td Pd 9550 Pn( hyo hyi) Pi ( h h ) yi ni (2) (3)
436 Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 (4) Gas engine output power is related to the operating modes of the whole system. When HPGHP system operates in mode D, output power, gas-consumed rate, thermal efficiency of gas engine and the energy conversion efficiency can be calculated by the following formulas, ry Py G h r r When HPGHP system operates in mode C, the output power of gas engine should be calculated by two parts, the output power drives compressor of heat pump; another part of the output power drives generator to recharge the battery pack. Because the batterys stored energy ultimately can be turned into the power to drive the compressor, so the energy change of the battery should be concluded in the calculation of the economic analysis of HPGHP system. The article uses the concept of equivalent output power of gas engine, equivalent gas-consumed rate, equivalent thermal efficiency of gas engine and equivalent energy conversion efficiency in the calculation process, which can be achieved by the following equations (9) (10) (11) Py Py ' ry (12) G' h G h ) r r r r b f fd d n bc (5) (6) (7) (8) When HPGHP system operates in mode E, the power of compressor comes from two parts, the output power of gas engine, another part of the power is electrical energy which comes from battery pack. So, SOC value variation still should be taken into calculation of the economic analysis of HPGHP system. equivalent output power of gas engine, equivalent gas-consumed rate, equivalent thermal efficiency of gas engine and equivalent energy conversion efficiency are still applied to analyze power and efficiency of HPGHP system, which is represented by the following correlations. (13)
Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 437 ' rc P G h G h y y 2 2 ' r r r r b f fd d n bc bf P (14) (15) (16) 4. Experimental results and analysis of LiFePO4 battery HPGHP 4.1. Performance of heat pump Due to experimental conditions, heating performance in winter was mainly tested in this experiment. The specific outdoor parameters of test condition are shown in Table 3. Five working conditions were respectively operated in this research to test energy conservation and emissions reduction effect of LiFePO4 battery HPGHP system. Performance of mode C, mode D and mode E were especially analyzed. Table 3. Outdoor parameters of test condition Outdoor dry bulb temperature Evaporating temperature Condensing temperature 9 C -3C 45C Heating capacity[kw] 34 32 30 28 26 24 22 20 18 mode C mode D mode E COP 4.8 4.6 4.4 4.2 4.0 3.8 3.6 mode C mode D mode E 16 3.4 14 3.2 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Speed of compressor[rpm] Speed of compressor[rpm] Figure. 4. The relation of compressor speed, heating capacity and COP in three operation modes. Figure 4 describes the relation between heating capacity, COP of heat pump and the speed of compressor. It can be seen that the heating capacity increases with increasing compressor speed but COP of heat pump decreases with the increase of compressor speed. With the increase in the speed of compressor from 700rpm to 2500rpm, both the heating capacity and COP show an approximately linear trend. As is shown in the figure, heating capacity increases from 14.52 to 33.13kW, while coefficient of performance decreases from 4.76 to 3.25. 4.2. Efficiency of power system Due to the high charging-discharging efficiency of LiFePO4 battery, power system can save more energy than the lead-acid battery system, especially in mode C and mode E, which need high energy storage or release efficiency.
438 Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 Figure 5 shows Gas engine thermal efficiency curves of LiFePO4 battery HPGHP system and lead-acid battery HPGHP system. The engine thermal efficiency of both HPGHP systems in the all three modes increased firstly to a maximum value, and then decreases with the increasing compressor speed. The experiment results show that engine thermal efficiency of LiFePO4 battery HPGHP system reaches its maximum value approximately 0.268, 0.282 and 0.291 when the system is operated in mode C, mode D and mode E. Compared with the corresponding value 0.235, 0.277 and 0.27 of lead-acid battery HPGHP system, LiFePO4 battery HPGHP system can always keep the gas engine more effective than lead-acid battery HPGHP system in different loads. The average growth rates are respectively 13.2%, 2%, and 7.6% in mode C, mode D and mode E. Thermal efficiency of the engine 0.32 0.30 0.28 0.26 0.24 0.22 0.20 0.18 mode C(HPGHP based on LiFePO4 battery) mode D(HPGHP based on LiFePO4 battery) mode E(HPGHP based on LiFePO4 battery) mode C(HPGHP based on lead-acid battery) mode D(HPGHP based on lead-acid battery) mode E(HPGHP based on lead-acid battery) 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Speed of compressor[rpm] Figure 5. The relation between thermal efficiency of gas engine and compressor speed Gas-consumed rate [g(kwh) -1 ] 420 400 380 360 340 320 300 280 260 mode C(HPGHP based on LiFePO4 battery) mode D(HPGHP based on LiFePO4 battery) mode E(HPGHP based on LiFePO4 battery) mode C(HPGHP based on lead-acid battery) mode D(HPGHP based on lead-acid battery) mode E(HPGHP based on lead-acid battery) 240 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Speed of compressor [rpm] Figure 6. The relation between gas-consumed rate and compressor speed Gas-consumed rate is the ratio of the gas consumed flow and the out power of gas engine. From the mathematic formula of engine thermal efficiency f and gas-consumed rate gr in third chapter of this article we can know that gas-consumed rate is inversely proportional to engine thermal efficiency. Figure 6 describes the relation between gasconsumed rate and compressor speed of both LiFePO4 battery HPGHP system and lead-acid battery HPGHP system. Both curves decreased firstly to a minimum value and then increased with the increasing speed of compressor. Compared the minimum gas-consumed rate value 291 g(kwh)-1, 276 g(kwh)-1 and 268 g(kwh)-1 of LiFePO4 battery HPGHP system with the corresponding value 331 g(kwh)-1, 282 g(kwh)-1 and 288 g(kwh)-1 of lead-acid battery HPGHP system, we can conclude that using LiFePO4 battery as the auxiliary power source of power system can be more energy-saving. The average reduction rates of gas-consumed rate are respectively 11.28%, 1.66% and 6.56% in low-load region, medium-load region and high-load region. 4.3. Economical performance analysis of LiFePO4 battery HPGHP system This article mainly discusses the energy conversion and recovery of HPGHP to measure economical performance of the new system. Figure 7 shows the energy conversion efficiency curves of LiFePO4 battery HPGHP system, leadacid battery HPGHP system and conventional GHP system. All of the three curves have the same fluctuating trend with the increasing compressor speed in three working modes. The average energy conversion efficiency value of LiFePO4 battery HPGHP system is about 0.208, 0.203 and 0.162 in mode C, mode D and mode E. Compared with the corresponding average value 0.168, 0.2, 0.13 of conventional GHP system and 0.195, 0.2, 0.147 of lead-acid battery HPGHP system, the energy conversion efficiency of LiFePO4 battery HPGHP is about 24.02%, 1.55%, 24.55% higher than conventional GHP and 6.6%, 1.2%, 10.2% higher than lead-acid battery HPGHP under low-load condition, medium-load condition and high-load condition.
Wenxiu Ji et al. / Procedia Engineering 146 ( 2016 ) 431 440 439 Energy conversion efficiency 0.24 0.22 0.20 0.18 0.16 0.14 0.12 0.10 HPGHP based on LiFePO4 battery HPGHP based on lead-acid battery conventional GHP 600 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Speed of compressor [rpm] Figure 7. The relation between energy conversion efficiency and compressor speed Reclaimed heat [kw] 16 14 12 10 8 6 4 2 heat reclaimed from jacket of HPGHP heat reclaimed from jacket of GHP heat reclaimed from exhaust of HPGHP heat reclaimed from exhaust of GHP total reclaimed heat of HPGHP total reclaimed heat of GHP 0 600 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Speed of compressor [rpm] Figure 8. The relation between reclaimed heat and compressor speed The hybrid-power gas engine heat pump system as a new gas-driven heat pump, it not only can save more gas energy, but also can retain another obvious advantage of conventional gas heat pump: energy recovery(wang and Cai 2013). Figure 8 displays relation between reclaimed heat and compressor speed of both HPGHP and GHP system. Heat reclaimed from jacket, heat reclaimed from exhaust and total reclaimed heat is closely related to the compressor speed. Conventional GHP reclaimed heat monotonically increases with the compressor speed, while HPGHP reclaimed heat has a reductive fluctuation when compressor speed is 1200rpm and1950 rpm, so HPGHP reclaimed less heat than traditional GHP. We can calculate that the average total reclaimed heat of LiFePO4 battery HPGHP system is respectively 12.43% and 10.2% lower than conventional GHP in jacket and exhaust heat exchanger. As a result, the total reclaimed heat of LiFePO4 battery HPGHP is 11.82% lower than GHP, owing to that the engine speed is lower than conventional GHP under high-load condition when gas engine and motor drives the compressor together. 5. Conclusion (1)In this paper, a coaxial LiFePO4 battery hybrid-power gas engine heat pump system is built, operated under logic threshold control strategy and five working modes. (2)Test research on COP, heating capacity, engine thermal efficiency and gas-consumed rate, were operated to verify the performance of heat pump and dynamic efficiency of power system of LiFePO4 battery HPGHP. Experiment results show that COP decreases from 4.76 to 3.25 and heating capacity increases from 14.52 to 33.13kW when compressor speed increases from 700rpm to 2500rpm; equivalent engine thermal efficiency reaches its maximum value approximately 0.268, 0.282 and 0.291 and equivalent gas-consumed rate reaches its minimum value about 291 g(kwh)-1, 276 g(kwh)-1 and 268 g(kwh)-1 when the system is operated in mode C, mode D and mode E. (3)Economical performances of containing LiFePO4 battery technology with HPGHP are especially compared with the previous lead-acid battery HPGHP and conventional GHP. Equivalent energy conversion efficiency of LiFePO4 battery HPGHP is about 24.02%, 1.55%, 24.55% higher than conventional GHP and 6.6%, 1.2%, 10.2% higher than lead-acid battery HPGHP separately for low-load condition, medium-load condition and high-load condition. The total reclaimed heat is 11.82% lower than GHP under the same load. Obviously, LiFePO4 battery HPGHP can achieve an obvious energy saving effect, especially in low-load condition and high-load condition.
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