压缩空气储能与吸收式热泵循环集成的热电联产系统

doi:10.19799/j.cnki.2095-4239.2020.0307

摘要/Abstract

摘要：

压缩空气储能与可再生能源相结合被认为是一种解决传统压缩空气储能系统对化石燃料的依赖、增加可再生能源渗透率的有效途径。通过将压缩空气储能系统与电加热器集成(CH-CAES)，大幅提升了储热装置的蓄热量，同时实现了压缩空气储能系统膨胀机做功能力的提升。为了回收压缩空气储能系统中储热装置剩余的高温余热，提出一种CH-CAES与吸收式热泵循环(AHP)集成的热电联产系统(CH-CAES-AHP)，以实现能量的梯级利用。采用控制变量法探究了4个关键参数对系统性能的影响。同时应用基于热力学第二定律的?分析方法作为能量分析的有益补充，完善对系统性能的评价。研究结果表明，通过集成AHP可大大提升CH-CAES系统的循环效率，增加能量的利用率。基本工况下，与CH-CAES系统相比，由于CH-CAES-AHP系统额外输出了5790.53 kW供热功率，集成系统的循环效率与?效率分别提升了29.96%和1.87%。参数分析发现：释能压力、电加热温度对集成系统性能影响较大，精馏塔压力、精馏塔回流比对集成系统性能影响较小。集成系统的循环效率随系统释能压力的升高而降低，随电加热温度的升高而升高；通过降低精馏塔压力、减小回流比可以增加热泵循环的净放热量，提升热泵性能系数，有利于集成系统循环效率的提高。集成系统的?效率随系统释能压力的升高而升高，随电加热温度的升高而降低；精馏塔压力、精馏塔回流比对集成系统?效率的影响不明显。

关键词: 压缩空气储能, 电加热, 氨水吸收式循环, 热力学分析

Abstract:

Combining compressed air energy storage (CAES) and renewable energy is recognized as an effective way to solve the dependence of the conventional compressed air energy storage system on fossil fuels and to increase the renewable energy penetration. In this paper, by integrating the CAES with an electrical heater (CH-CAES), the amount of heat storage in the thermal storage device is greatly improved, and, simultaneously, the capacity of the expander to output mechanical power in the compressed air energy storage system is improved. To recover the high temperature residual heat of the thermal storage device in the CAES, a novel combined heat and power system (CH-CAES-AHP) coupled with the CH-CAES and absorption heat pump cycle (AHP) is proposed in this paper for achieving the cascade utilization of energy. Parametric analyses were carried out in this paper to investigate the effect of four key parameters on the integration system performance using the control variable method. Meanwhile, the exergy analysis method based on the second law of thermodynamics was applied as a beneficial supplement to the energy analysis method to improve the evaluation of the system performance. The results show that the round-trip efficiency of the CH-CAES is greatly improved, also improving the energy utilization rate by integrating with the AHP. Under the fundamental working conditions, the round-trip efficiency and exergy efficiency of the CH-CAES-AHP increased by 29.96% and 1.87%, respectively, due to the integration system output being an additional 5790.53 kW heating power compared with the CH-CAES. The parametric analysis shows that the discharging pressure and the electrical heating temperature have a great influence on the performance of the integration system, while the rectification column pressure and the rectifier reflux ratio have little influence on the performance of the integration system. The parametric analysis also shows that the round-trip efficiency of the integration system is decreased with the discharging pressure and increased with the electrical heating temperature. Moreover, reducing the rectification column pressure and the rectifier reflux ratio can lead to more net heat being released by the ammonia absorption heat pump cycle and increasing the performance coefficient of the AHP; this is conducive to the improvement of the round-trip efficiency of the integration system. Simultaneously, the exergy efficiency of the integration system is increased with the discharging pressure and decreased with the electrical heating temperature, while the rectification column pressure and the rectifier reflux ratio have little influence on the exergy efficiency of the integration system.

Key words: compressed air energy storage, electrical heating, ammonia absorption cycle, thermodynamic analysis

中图分类号:

TK 02

杨绪青, 余真珠, 杨肖虎, 刘　展. 压缩空气储能与吸收式热泵循环集成的热电联产系统[J]. 储能科学与技术, 2021, 10(1): 362-369.

Xuqing YANG, Zhenzhu YU, Xiaohu YANG, Zhan LIU. Combined heating and power system coupled with compressed air energy storage and absorption heat pump cycle[J]. Energy Storage Science and Technology, 2021, 10(1): 362-369.

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参考文献 15

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参数	数值
环境温度/K	293.15
环境压力/kPa	101.3
储能压力/kPa	7200
释能压力/kPa	4600
电加热温度/K	573.15
膨胀机额定输出功率/kW	10000
冷却器夹点温差/K	20
再热器夹点温差/K	20
回热器夹点温差/K	20
溶液热交换器夹点温差/K	10
加热器夹点温差/K	10
压缩机等熵效率	0.84
膨胀机等熵效率	0.88
泵等熵效率	0.70
冷凝压力/kPa	1783
蒸发压力/kPa	616.3
精馏塔回流比	0.4
氨水浓溶液氨水溶度	0.4813

参数/指标	CH-CAES-AHP系统	CH-CAES系统
压缩机功率/kW	12322.49	12322.49
电加热器功率/kW	7005.58	7005.58
膨胀机功率/kW	10000	10000
供热量/kW	5790.53	0
供热?/kW	361.13	0
净放热量/kW	1301.43	0
系统循环效率η/%	81.70	51.74
系统?效率β/%	53.61	51.74

状态点	工作流体	温度/K	压力/kPa	质量流量/kg·s^-1	氨浓度/%
01	氨水	318.15	616.3	7.86	48.13
02	氨水	318.42	1783	7.86	48.13
03	氨水	361.70	1783	7.86	48.13
04	氨	320.41	1783	1.94	99.99
05	氨水	361.71	1783	8.33	50.20
06	氨	318.23	1783	0.78	99.99
07	氨水	379.62	1783	1.64	95.53
08	氨	318.23	1783	1.17	99.99
09	氨	283.24	616.3	1.17	99.99
010	氨	290.04	616.3	1.17	99.99
011	氨水	379.62	1783	6.69	39.10
012	氨水	328.42	1783	6.69	39.10
013	氨水	328.67	616.3	6.69	39.10

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