Assessment on Partial Derivatives for Thermal-Physical Properties of Carbon Dioxide

Shuang Wen, Q. Wen
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Abstract

To adapt to a requirement of improving the accuracy and efficiency of calculation, a full or partial implicit scheme is usually employed in solving the conservative equations of the supercritical carbon dioxide (S-CO2) Brayton cycle, and partial derivatives of thermal properties such as (∂h/∂ρ)p and (∂h/∂p)ρ are needed in numerical solver. In this paper, the most representative state equations of carbon dioxide are investigated and evaluated by experimental data. The Span-Wagner (SW) equation has a minimal error in all state equations, so the SW equation is chosen as the fundamental equation of thermal properties for partial derivatives. Based on that, the equations of partial derivatives such as (∂h/∂ρ)p and (∂h/∂p)ρ are presented by the Maxwell equation. The paper also evaluates the closure of partial derivatives equations. The deviations of (∂h/∂ρ)p and (∂h/∂p)ρ are within ±0.01% for most points. The maximum closure error of (∂h/∂ρ)p is 0.373%, and the maximum one of (∂h/∂p)ρ is −0.798%. Therefore, the partial derivatives equations obtained in this paper can play a significant role in the safety analysis code.
二氧化碳热物性的偏导数评价
为了适应提高计算精度和效率的要求,通常在求解超临界二氧化碳(S-CO2)布雷顿循环的保守方程时采用全隐式或部分隐式格式,并且在数值求解器中需要有热性质的偏导数,如(∂h/∂ρ)p和(∂h/∂p)ρ。本文用实验数据对最具代表性的二氧化碳状态方程进行了研究和评价。Span-Wagner (SW)方程在所有状态方程中误差最小,因此选择Span-Wagner方程作为热物性偏导数的基本方程。在此基础上,通过Maxwell方程给出了(∂h/∂ρ)p和(∂h/∂p)ρ等偏导数的方程。本文还对偏导数方程的闭包性进行了评价。对于大多数点,(∂h/∂ρ)p和(∂h/∂p)ρ的偏差在±0.01%以内。(∂h/∂ρ)p的最大闭合误差为0.373%,(∂h/∂p)ρ的最大闭合误差为−0.798%。因此,本文所得到的偏导数方程可以在安全分析规范中发挥重要作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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