This paper discussed the experimental results of the performance of an organic Rankine cycle(ORC)system with an ultra-low temperature heat source.The low boiling point working medium R134a was adopted in the system.Th...This paper discussed the experimental results of the performance of an organic Rankine cycle(ORC)system with an ultra-low temperature heat source.The low boiling point working medium R134a was adopted in the system.The simulated heat source temperature(SHST)in this work was set from 39.51°C to 48.60°C by the simulated heat source module.The influence of load percentage of simulated heat source(LPSHS)between 50%and 70%,the rotary valve opening(RVO)between 20%and 100%,the resistive load between 36Ωand 180Ωor the no-load of the generator,as well as the autumn and winter ambient temperature on the system performance were studied.The results showed that the stability of the system was promoted when the generator had a resistive load.The power generation(PG)and generator speed(GS)of the system in autumn were better than in winter,but the expander pressure ratio(EPR)was lower than in winter.Keep RVO unchanged,the SHST,the mass flow rate(MFR)of the working medium,GS,and the PG of the system increased with the increasing of LPSHS for different generator resistance load values.When the RVO was 60%,LPSHS was 70%,the SHST was 44.15°C and the resistive load was 72Ω,the highest PG reached 15.11 W.Finally,a simulation formula was obtained for LPSHS,resistance load,and PG,and its correlation coefficient was between 0.9818 and 0.9901.The formula can accurately predict the PG.The experimental results showed that the standard deviation between the experimental and simulated values was below 0.0792,and the relative error was within±5%.展开更多
构建高效、无污染的动力发电系统是解决目前能源紧缺和环境污染问题的有效手段。以Capstone公司生产的C65型微型燃气轮机为核心发电部件,耦合了太阳能驱动氨气分解制氢的热化学过程,实现了可再生能源和氨气化学能之间的多能互补,采用有...构建高效、无污染的动力发电系统是解决目前能源紧缺和环境污染问题的有效手段。以Capstone公司生产的C65型微型燃气轮机为核心发电部件,耦合了太阳能驱动氨气分解制氢的热化学过程,实现了可再生能源和氨气化学能之间的多能互补,采用有机朗肯循环(ORC)作为底循环回收微型燃气轮机(微燃机,MGT)产生的烟气余热并发电,实现能量梯级利用。在化工模拟软件Aspen Plus中构建了详细的模拟流程,进行系统热力性能分析,结果表明:通过太阳能和氨气的互补提高了富氢合成气热值,微燃机输出功率为89.95 k W,比参考系统中的C65微燃机多24.95k W;该系统在设计工况下的电效率达到了44.81%,[火用]效率为47.97%,分别比参考系统高出8.51百分点和9.67百分点;系统中最大的?损部件为燃烧室,占到了总[火用]损的41.67%,其次蒸发器和回热器分别占14.31%和11.15%;系统电效率和[火用]效率随着太阳能集热量的增加分别呈减小和增大的趋势。该研究结果可为以氨气为燃料并耦合太阳能的分布式微燃机发电系统提供参考。展开更多
燃机+底层循环是目前可行性高、效率高、变负荷能力强的重要分布式能源技术,目前成熟的燃机底层循环是传统的蒸汽朗肯循环。为进一步提高燃机综合利用效率,寻找到可以更好的与燃机余热热源匹配并最大化余热发电量的新型底层循环,研究分...燃机+底层循环是目前可行性高、效率高、变负荷能力强的重要分布式能源技术,目前成熟的燃机底层循环是传统的蒸汽朗肯循环。为进一步提高燃机综合利用效率,寻找到可以更好的与燃机余热热源匹配并最大化余热发电量的新型底层循环,研究分析了包括有机朗肯循环(organic rankine cycles,ORC),超临界二氧化碳(supercritical carbon dixide,S-CO_(2))布雷顿循环,以及其组合形式。采用模拟计算的方法,理论分析了S-CO_(2)布雷顿循环与ORC联合循环余热利用的整体效果。对回热器和烟气加热器进行了?损失分析,对透平、压缩机、泵等设备进行了能量分析,揭示了各种循环性能优劣的本质。结果显示,几种新形式联合循环的余热发电量都比电厂原有蒸汽循环发电量大,本文提出的S-CO_(2)布雷顿循环与ORC联合循环可以比美国电力研究所(Electric Power Research Institute,EPRI)提出的复杂S-CO_(2)布雷顿循环相对多提供4.2%的余热发电量,并且本文的新型联合循环参数耦合效应弱,操作性更强。展开更多
为降低CO_(2)排放,提高能源利用效率,该文建立超超临界二次再热-碳捕集集成系统。利用碳捕集汽轮机排汽为再沸器提供能量,并在集成系统基础上提出3种优化方法。结果表明,3种优化方案都提高了机组效率和热力性能,热效率分别提高0.508%、1...为降低CO_(2)排放,提高能源利用效率,该文建立超超临界二次再热-碳捕集集成系统。利用碳捕集汽轮机排汽为再沸器提供能量,并在集成系统基础上提出3种优化方法。结果表明,3种优化方案都提高了机组效率和热力性能,热效率分别提高0.508%、1.314%和4.817%,对应煤耗分别降低4.514g/(kW×h)、11.428g/(kW×h)、39.440g/(kW×h)。当设定碳捕集率为96%、CO_(2)再生能耗为3.8GJ/t时,对集成系统及3种优化系统进行技术经济性分析与㶲分析。通过分析可知,方案III的平均发电成本(the levelized cost of energy,LCOE)和CO_(2)减排成本最低;㶲分析表明高压加热器的㶲效率、㶲损普遍高于低压加热器。3种方案中,方案Ⅲ的高压加热器㶲效率明显高于方案Ⅰ与方案Ⅱ,从系统各设备㶲分析对比来看锅炉㶲效率最低。与锅炉相比较汽轮机的㶲损失相对较小,其中超高压缸和低压缸㶲损失所占比例相对较大。展开更多
With increasing awareness of energy conservation and environmental protection, the Organic Rankine Cycle (ORC) system has gained significant attention. This technology enables the recovery of industrial waste heat, wa...With increasing awareness of energy conservation and environmental protection, the Organic Rankine Cycle (ORC) system has gained significant attention. This technology enables the recovery of industrial waste heat, waste incineration heat, and renewable energy sources such as geothermal heat, biomass energy, and solar energy at lower temperatures. However, the low-grade heat source utilized in ORC systems faces a challenge to achieving high power generation efficiency and output power. Therefore, enhancing the power generation capacity of ORC systems is a key research focus in this field. An entranced heat exchanger ORC system with the screw expander driven by the low-temperature heat source is established to investigate the relevant performance. Hot water temperature from 77°C to 132°C is adopted for performance analysis, while the environmental temperature is approximately 25°C. Refrigerant R245fa is selected as the working fluid, and the screw expander is employed for power generation. It is worth noting that the entranced heat exchanger ORC system has significant potential for low-temperature heat recovery. Experimental results indicate that the maximum power output is 12.83 kW, which is obtained at around 105°C hot water inlet temperature. Correspondingly, the average power output remains 11.75 kW, revealing the system’s high stability for power generation. The implementation of a plate heat exchanger for enhanced heat transfer has enabled a 50% reduction in system size compared to traditional shell-tube type ORC systems. Besides, economic calculations demonstrate substantial benefits associated with the ORC system. The calculations indicate an internal benefit of 560,000 RMB/year, accompanied by notable external benefits such as an energy saving and emission reduction potential of up to 784 t CO2 per year. Moreover, the payback period is 2.23 years. It shows a remarkable improvement in terms of performance and excellent economic benefits. As a result, the novel ORC presents a promising alternative for low-grade heat utilization as compared to conventional small-scale ORC systems.展开更多
目的以RNA干扰抑制血管平滑肌细胞(vascu lar smooth musc le cells,VSMCs)ORC1基因,探讨ORC1基因表达抑制后VSMCs增殖的变化。方法实验设置正常对照组、阴性siRNA组及阳性(ORC1+A、ORC1+B、ORC1+C)siR-NA组。应用W estern b lot检测ORC...目的以RNA干扰抑制血管平滑肌细胞(vascu lar smooth musc le cells,VSMCs)ORC1基因,探讨ORC1基因表达抑制后VSMCs增殖的变化。方法实验设置正常对照组、阴性siRNA组及阳性(ORC1+A、ORC1+B、ORC1+C)siR-NA组。应用W estern b lot检测ORC1基因表达的变化;应用MTT比色试验、3H-TdR掺入试验检测VSMCs增殖的情况。免疫细胞化学染色观察增殖细胞核抗原(proliferating cell nuc lear antigen,PCNA)表达。结果①siRNA转染后,3个阳性siRNA转染组ORC1基因表达水平均降低,尤以第2对阳性siRNA抑制效果最为显著,而空白对照组及阴性对照组间ORC1基因表达水平无显著差异。②siRNA转染使ORC1表达减弱后,VSMCs的MTT吸光度值3、H-TdR掺入量和PCNA表达量均较空白对照组及阴性对照组显著降低。结论RNA干扰介导的ORC1基因沉寂可显著抑制VSMCs增殖。展开更多
基金This work was supported by Tianjin Natural Science Foundation(No.21JCZDJC00750).
文摘This paper discussed the experimental results of the performance of an organic Rankine cycle(ORC)system with an ultra-low temperature heat source.The low boiling point working medium R134a was adopted in the system.The simulated heat source temperature(SHST)in this work was set from 39.51°C to 48.60°C by the simulated heat source module.The influence of load percentage of simulated heat source(LPSHS)between 50%and 70%,the rotary valve opening(RVO)between 20%and 100%,the resistive load between 36Ωand 180Ωor the no-load of the generator,as well as the autumn and winter ambient temperature on the system performance were studied.The results showed that the stability of the system was promoted when the generator had a resistive load.The power generation(PG)and generator speed(GS)of the system in autumn were better than in winter,but the expander pressure ratio(EPR)was lower than in winter.Keep RVO unchanged,the SHST,the mass flow rate(MFR)of the working medium,GS,and the PG of the system increased with the increasing of LPSHS for different generator resistance load values.When the RVO was 60%,LPSHS was 70%,the SHST was 44.15°C and the resistive load was 72Ω,the highest PG reached 15.11 W.Finally,a simulation formula was obtained for LPSHS,resistance load,and PG,and its correlation coefficient was between 0.9818 and 0.9901.The formula can accurately predict the PG.The experimental results showed that the standard deviation between the experimental and simulated values was below 0.0792,and the relative error was within±5%.
文摘构建高效、无污染的动力发电系统是解决目前能源紧缺和环境污染问题的有效手段。以Capstone公司生产的C65型微型燃气轮机为核心发电部件,耦合了太阳能驱动氨气分解制氢的热化学过程,实现了可再生能源和氨气化学能之间的多能互补,采用有机朗肯循环(ORC)作为底循环回收微型燃气轮机(微燃机,MGT)产生的烟气余热并发电,实现能量梯级利用。在化工模拟软件Aspen Plus中构建了详细的模拟流程,进行系统热力性能分析,结果表明:通过太阳能和氨气的互补提高了富氢合成气热值,微燃机输出功率为89.95 k W,比参考系统中的C65微燃机多24.95k W;该系统在设计工况下的电效率达到了44.81%,[火用]效率为47.97%,分别比参考系统高出8.51百分点和9.67百分点;系统中最大的?损部件为燃烧室,占到了总[火用]损的41.67%,其次蒸发器和回热器分别占14.31%和11.15%;系统电效率和[火用]效率随着太阳能集热量的增加分别呈减小和增大的趋势。该研究结果可为以氨气为燃料并耦合太阳能的分布式微燃机发电系统提供参考。
文摘燃机+底层循环是目前可行性高、效率高、变负荷能力强的重要分布式能源技术,目前成熟的燃机底层循环是传统的蒸汽朗肯循环。为进一步提高燃机综合利用效率,寻找到可以更好的与燃机余热热源匹配并最大化余热发电量的新型底层循环,研究分析了包括有机朗肯循环(organic rankine cycles,ORC),超临界二氧化碳(supercritical carbon dixide,S-CO_(2))布雷顿循环,以及其组合形式。采用模拟计算的方法,理论分析了S-CO_(2)布雷顿循环与ORC联合循环余热利用的整体效果。对回热器和烟气加热器进行了?损失分析,对透平、压缩机、泵等设备进行了能量分析,揭示了各种循环性能优劣的本质。结果显示,几种新形式联合循环的余热发电量都比电厂原有蒸汽循环发电量大,本文提出的S-CO_(2)布雷顿循环与ORC联合循环可以比美国电力研究所(Electric Power Research Institute,EPRI)提出的复杂S-CO_(2)布雷顿循环相对多提供4.2%的余热发电量,并且本文的新型联合循环参数耦合效应弱,操作性更强。
文摘为降低CO_(2)排放,提高能源利用效率,该文建立超超临界二次再热-碳捕集集成系统。利用碳捕集汽轮机排汽为再沸器提供能量,并在集成系统基础上提出3种优化方法。结果表明,3种优化方案都提高了机组效率和热力性能,热效率分别提高0.508%、1.314%和4.817%,对应煤耗分别降低4.514g/(kW×h)、11.428g/(kW×h)、39.440g/(kW×h)。当设定碳捕集率为96%、CO_(2)再生能耗为3.8GJ/t时,对集成系统及3种优化系统进行技术经济性分析与㶲分析。通过分析可知,方案III的平均发电成本(the levelized cost of energy,LCOE)和CO_(2)减排成本最低;㶲分析表明高压加热器的㶲效率、㶲损普遍高于低压加热器。3种方案中,方案Ⅲ的高压加热器㶲效率明显高于方案Ⅰ与方案Ⅱ,从系统各设备㶲分析对比来看锅炉㶲效率最低。与锅炉相比较汽轮机的㶲损失相对较小,其中超高压缸和低压缸㶲损失所占比例相对较大。
文摘With increasing awareness of energy conservation and environmental protection, the Organic Rankine Cycle (ORC) system has gained significant attention. This technology enables the recovery of industrial waste heat, waste incineration heat, and renewable energy sources such as geothermal heat, biomass energy, and solar energy at lower temperatures. However, the low-grade heat source utilized in ORC systems faces a challenge to achieving high power generation efficiency and output power. Therefore, enhancing the power generation capacity of ORC systems is a key research focus in this field. An entranced heat exchanger ORC system with the screw expander driven by the low-temperature heat source is established to investigate the relevant performance. Hot water temperature from 77°C to 132°C is adopted for performance analysis, while the environmental temperature is approximately 25°C. Refrigerant R245fa is selected as the working fluid, and the screw expander is employed for power generation. It is worth noting that the entranced heat exchanger ORC system has significant potential for low-temperature heat recovery. Experimental results indicate that the maximum power output is 12.83 kW, which is obtained at around 105°C hot water inlet temperature. Correspondingly, the average power output remains 11.75 kW, revealing the system’s high stability for power generation. The implementation of a plate heat exchanger for enhanced heat transfer has enabled a 50% reduction in system size compared to traditional shell-tube type ORC systems. Besides, economic calculations demonstrate substantial benefits associated with the ORC system. The calculations indicate an internal benefit of 560,000 RMB/year, accompanied by notable external benefits such as an energy saving and emission reduction potential of up to 784 t CO2 per year. Moreover, the payback period is 2.23 years. It shows a remarkable improvement in terms of performance and excellent economic benefits. As a result, the novel ORC presents a promising alternative for low-grade heat utilization as compared to conventional small-scale ORC systems.
文摘目的以RNA干扰抑制血管平滑肌细胞(vascu lar smooth musc le cells,VSMCs)ORC1基因,探讨ORC1基因表达抑制后VSMCs增殖的变化。方法实验设置正常对照组、阴性siRNA组及阳性(ORC1+A、ORC1+B、ORC1+C)siR-NA组。应用W estern b lot检测ORC1基因表达的变化;应用MTT比色试验、3H-TdR掺入试验检测VSMCs增殖的情况。免疫细胞化学染色观察增殖细胞核抗原(proliferating cell nuc lear antigen,PCNA)表达。结果①siRNA转染后,3个阳性siRNA转染组ORC1基因表达水平均降低,尤以第2对阳性siRNA抑制效果最为显著,而空白对照组及阴性对照组间ORC1基因表达水平无显著差异。②siRNA转染使ORC1表达减弱后,VSMCs的MTT吸光度值3、H-TdR掺入量和PCNA表达量均较空白对照组及阴性对照组显著降低。结论RNA干扰介导的ORC1基因沉寂可显著抑制VSMCs增殖。