混合制冷剂R1234yf/R32 PVTx性质的实验研究

为了获得混合制冷剂R1234yf/R32的热物性数据,本文以Burnett法为基础搭建了高精度PVTx实验台,在温度为253~313 K时,测定了质量分数为15%/85%和25%/75%混合制冷剂R1234yf/R32的PVT性质,拟合了两种不同配比的混合工质的气态维里方程,为进一步研究该工质的基础热物性提供了详实的数据。     

近共沸制冷剂R290/R134a PVTx性质的实验研究

为了获得混合制冷剂R134a/R290的热物性数据,搭建了高精度PVTx实验系统。以Burnett法为基础,测定了R134a/R290质量分数为50%/50%、55%/45%和60%/40%在温度为252 K~320 K的PVT性质,并且拟合了三种不同配比的混合工质的气态维里方程。实验数据与方程的平均误差为1%左右,具有较好的重合度。     

R32和R32/R1234yf混合工质黏度实验测量及模型

本文针对含HFOs类混合制冷剂黏度开展实验和模型研究。采用振动弦法黏度计对R32纯质和R32/R1234yf混合制冷剂黏度进行了实验测量,测量的温度范围分别为263~350 K、263~360 K,压力最高均为30 MPa,实验系统黏度测量的不确定度为2%。本文共获得了177组实验数据,利用得到的实验数据,基于硬球模型分别拟合了R32纯质和R32/R1234yf混合制冷剂黏度方程。R32纯质黏度实验数据与方程的平均绝对偏差为0.28%,最大绝对偏差为0.92%;R32/R1234yf混合工质黏度实验数据与方程的平均绝对偏差为0.69%,最大绝对偏差为2.09%。由此可见,实验数据和黏度模型吻合较好,为R32和R32/R1234yf混合制冷剂的应用研究提供了重要参考依据。     

HFO-1234yf——新一代汽车空调制冷剂

介绍一种新型的应用于汽车空调系统的制冷剂HFO-1234yf。该制冷剂的典型特点是具有很低的全球变暖潜值（GWP=4）,且对于使用R134a制冷剂的汽车空调系统是一种潜在的且经济的直接替代方案。汽车空凋台架测试和实车性能试验的结果表明,直接充注HFO-1234yf制冷剂后,系统制冷量和COP与原R134a系统偏差均在5％左右。关于材料相容性方面,均可以直接使用POE和PAG润滑油,与橡胶的兼容性及软管密封性方面未见不良反应。危险性试验评估结果显示,该制冷剂为低毒性,且毒性低于R134a;实车泄漏试验测试表明,制冷剂泄漏时,遇到明火不会导致燃烧加剧。     

制冷剂R1234yf替代R22的理论分析和试验研究

从热工性能、环保特性、安全性以及试验研究等角度,讨论制冷剂R1234yf替代R22的优势。试验结果表明,R1234yf在高温工况(额定制冷T3)下的能效比较R22高2%,其排气温度比R22平均降低9.8℃,R1234yf的可燃性在可燃制冷剂中是较弱的。因此,R1234yf在高温工况区替代R22具有较大的潜力。     

R134a：制冷剂的最佳选择

外层空间臭氧层的耗损受到全球普遍关注,自从这一现象首次披露以来,空调制冷行业发生了巨大的变化。例如,多数离心冷冻设备制造商都在试图采用对大气无害的制冷剂,一些厂商采用螺杆压缩机代替离心压缩机。无论如何,使用无害制冷剂的新设备终将取代全球成千上万套旧式制冷装置。     

新型制冷剂R1234yf的性能分析

本文先介绍目前对制冷剂选择的要求,然后从热物理性质、材料兼容性、溶油性、热工性能等几个方面,比较新型制冷剂R1234yf与R32、R22及R717的优劣,讨论新型制冷剂在减排、安全、节能要求下发展前景。     

新型制冷剂HFO-1234yf

HFO-1234yf作为HFC-134a的替代物,已基本得到了欧洲主要汽车厂家的认可。本文介绍了HFO-1234yf的物理性能、制冷效率、可燃性、互溶性、材料相溶性、用途以及合成研究进展。     

R1234yf/R290/R134a系气液相平衡的模拟

本文从理论方面研究了混合制冷剂的相平衡特性,基于Peng-Robinson(PR)状态方程与Wong-Sandler(WS)混合法则,结合Predictive Soave Redlich Kwong(PSRK)方程中使用的UNIFAC基团贡献法,构建了混合物气液相平衡预测模型(PRWS-UNIFAC-PSRK)。结果表明:二元混合物R32/R1234yf的压力及气相质量分数的模拟结果与实验值偏差分别在±2.5%和±0.02内;三元混合物R134a/R1234yf/R600a的压力及气相组分质量分数计算值与实验数据的偏差基本在±3%和±0.04内;建立了R1234yf/R290/R134a系的三元相平衡图,当质量分数在0.25/0.70/0.05左右时存在共沸点。通过采用多参数状态方程,改进活度系数模型,获取更为准确的二元相互作用系数,可进一步提高模型的预测精度。     

Development and validation of a micro-fin tubes evaporator model using R134a and R1234yf as working fluids

This paper presents a model of shell and tube evaporator with micro-fin tubes using R1234yf and R134a. The model developed for this evaporator uses the ε-NTU method to predict the evaporating pressure, the refrigerant outlet enthalpy and the outlet temperature of the secondary fluid. The model accuracy is evaluated using different two-phase flow boiling correlations for micro-fin tubes and comparing predicted and experimental data. The experimental tests were carried out for a wide range of operating conditions using R134a and R1234yf as working fluids. The predicted parameter with maximum deviations, between the predicted and experimental data, is the evaporating pressure. The correlation of Akhavan– Behabadi et al. was used to predict flow boiling heat transfer, with an error on cooling capacity prediction below 5%. Simulations, carried out with this validated model, show that the overall heat transfer coefficient of R1234yf has a maximum decrease of 10% compared with R134a.     

新一代制冷剂HFO-1234yf的热物性模型

基于Peng-Robinson通用状态方程,采用基团贡献原理以及多项式拟合方法,建立了符合精度要求的新型LGWP制冷剂HFO-1234yf的热物性模型,并对模型进行了验证,利用数学软件对模型进行编程求解,得到了较为全面的HFO-1234yf制冷剂的热物性数据。将HFO-1234yf制冷剂与R134a及R417A制冷剂的热物性能进行了对比,结果显示HFO-1234yf的饱和蒸汽压力与定压比热容和R134a的表现相似,二者的饱和蒸气压均低于R417A,HFO-1234yf制冷剂与R134a和R417A相比,其饱和状态焓值较低,这将导致HFO-1234y系统运行时的性能系数不高。该模型能为HFO-1234yf制冷剂在汽车空调以及固定式空调制冷设备上的应用提供理论依据。     

R1234yf as a substitute of R134a in automotive air conditioning. Solubility measurements in two commercial PAG oils

Starting from January 1st 2011, as stated by the Directive 2006/40/EC, fluorinated greenhouse gases with a global warming potential (GWP) higher than 150 can not be used in automotive applications any more. For this reason, 1,1,1,2-tetrafluoroethane (R134a), commonly used for these applications, will be abandoned and substituted by refrigerants with lower GWP. In recent times, a new fluid, 2,3,3,3-tetrafluoroprop-1-ene (R1234yf) has been proposed as an interesting alternative, since it has a very low GWP and thermodynamic properties very similar to R134a. At the moment, only few data can be found on the thermodynamic properties of this new refrigerant and, in particular, its behaviour in solution with commonly used compressor lubricants is still to be evaluated. Here, solubility experimental data of R1234yf in a Polyalkylene Glycol (PAG) and in a specifically modified Double-Capped PAG (DC-PAG) commercial lubricants are measured with a static synthetic method at isothermal conditions, in the temperature range between 258 K and 338 K.     

新型制冷剂R1234ze(E)及其混合工质研究进展

低GWP值制冷剂R1234ze(E)(trans-1,3,3,3-tetrafluoropropene)作为R134a较为理想的替代品而被关注,但其单一成分的热力学性能和传输特性并不理想,在R1234ze(E)中混入R32成分可以有效改善其热力学性能。本文概述了低GWP值工质R1234ze(E)及其与R32混合物的热物性特征、传输特性及系统运行性能方面的研究现状,并与目前常用的制冷工质进行比较分析,指出R1234ze(E)与R32混合工质有望成为新型低GWP值替代工质。