How to select regenerative configurations of CO
            <sub>2</sub>
            transcritical Rankine cycle based on the temperature matching analysis

Tian, Hua; Xu, Zhiqiang; Liu, Peng; Wang, Xuan; Shu, Gequn

doi:10.1002/er.4945

Cited by 6 publications

(2 citation statements)

References 46 publications

(54 reference statements)

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“…Sánchez and Silva 29 indicated the size of a heat exchanger (namely evaporator and condenser) can be reduced by a recuperator. Tian et al 30 indicated a high impact of regenerative configurations on improving net power output, especially for split dual regenerative TRC. However, Ramy et al 31 indicated the recuperator had negative effects on compactness and performance.…”

Section: Introductionmentioning

confidence: 99%

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Hsieh

Cheng

Lai

2022

Energy Science & Engineering

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A thermodynamic model of basic and recuperative transcritical organic Rankine cycles (TRCs) associated with using five pure and six mixed fluids as working fluids has been developed. This model can be employed to investigate the effects of recuperators at inlet expander temperatures (Texp,in) of 150–200°C and inlet expander pressures (Pexp,in) of 3.7–6.9 MPa. The ratio of change (ROC) of the first‐ and second‐law efficiencies (ηI and ηII) was positively correlated with the heat transfer rate of the recuperator and exhibited an opposite trend for a specific volume ratio. ROC was substantially affected by operating parameters and working fluid. However, the recuperator heat transfer rate was negligibly affected by the mixture temperature glide (Tglide). A universal empirical equation of ηI,II was proposed for both TRC configurations. The equation, a function of the specific volume ratio, can predict the system efficiencies for pure and mixed fluids, even if a mixture has an arbitrary mole fraction. As Tglide of R600a‐base mixture and R245fa/R134a was lower than 16 K, they had low error rates and low standard deviations. Finally, the equation was highly accurate in ηII prediction, particularly at a Texp,in of 160°C and 170°C and a Pexp,in of 4.9–5.8 MPa.

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Section: Introductionmentioning

confidence: 99%

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Hsieh

Cheng

Lai

2022

Energy Science & Engineering

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“…In this research, a split dual regenerative transcritical Rankine cycle (SR-TRC) is investigated shown in Figure 1. Due to the design of split branches and two regenerators, the SR-TRC system can meet the requirement of recovering the jacket water and exhaust gas simultaneously and improve the temperature matching in the whole heat absorption process, and has been proved to be a novel cycle configuration to achieve better temperature match between the system and heat sources [36]. The concrete working process of SR-TRC is: the working fluid transferring heat from jacket water in the preheater (2-3) is split into two parts, namely, high-temperature branch (H-branch) and low-temperature branch (L-branch).…”

Section: Trc Configurationmentioning

confidence: 99%

Fluid Selection of Transcritical Rankine Cycle for Engine Waste Heat Recovery Based on Temperature Match Method

et al. 2020

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Engines waste a major part of their fuel energy in the jacket water and exhaust gas. Transcritical Rankine cycles are a promising technology to recover the waste heat efficiently. The working fluid selection seems to be a key factor that determines the system performances. However, most of the studies are mainly devoted to compare their thermodynamic performances of various fluids and to decide what kind of properties the best-working fluid shows. In this work, an active working fluid selection instruction is proposed to deal with the temperature match between the bottoming system and cold source. The characters of ideal working fluids are summarized firstly when the temperature match method of a pinch analysis is combined. Various selected fluids are compared in thermodynamic and economic performances to verify the fluid selection instruction. It is found that when the ratio of the average specific heat in the heat transfer zone of exhaust gas to the average specific heat in the heat transfer zone of jacket water becomes higher, the irreversibility loss between the working fluid and cold source is improved. The ethanol shows the highest net power output of 25.52 kW and lowest electricity production cost of $1.97/(kWh) among candidate working fluids.

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Multi-objective optimization and evaluation of supercritical CO2 Brayton cycle for nuclear power generation

Yu,

Cheng,

Zhang

et al. 2024

NUCL SCI TECH

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How to select regenerative configurations of CO ₂ transcritical Rankine cycle based on the temperature matching analysis

Cited by 6 publications

References 46 publications

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Fluid Selection of Transcritical Rankine Cycle for Engine Waste Heat Recovery Based on Temperature Match Method

Multi-objective optimization and evaluation of supercritical CO2 Brayton cycle for nuclear power generation

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How to select regenerative configurations of CO 2 transcritical Rankine cycle based on the temperature matching analysis

Cited by 6 publications

References 46 publications

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Energetic and exergetic efficiency comparison of recuperative transcritical organic Rankine cycles under different pure and mixture fluids

Fluid Selection of Transcritical Rankine Cycle for Engine Waste Heat Recovery Based on Temperature Match Method

Multi-objective optimization and evaluation of supercritical CO2 Brayton cycle for nuclear power generation

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How to select regenerative configurations of CO ₂ transcritical Rankine cycle based on the temperature matching analysis