超压缩机排气管道中的气体脉动特性分析

Jun Xiao, Maofei Geng
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引用次数: 0

摘要

为分析低密度聚乙烯(LDPE)压缩机管道系统中的气体脉动特性,提出了一种基于实际气体特性的压缩机管道气体脉动时域计算方法。首先,以气体状态参数为自变量和因变量,编制热物理性质表。然后根据实际气体特性建立一维非稳态流动方程和管道流动特性方程。在设定管道参数和边界条件后,采用两步法对管道内点的流动方程进行离散化。在边界点采用梯形积分法对特征方程进行离散化。这样,就实现了管道中脉动流场的时域求解。利用自主开发的数值代码对双级超压缩机排气管道中的气体脉动进行了时域计算和分析。根据实际气体性质计算出的压力脉动曲线与实验数据吻合良好,最大差值低于局部平均压力的 4%,小于根据平面波理论计算出的结果与实测数据的差值。气体脉动特性分析表明,主管道内的压力脉动主要由基波和二次谐波引起。安全阀支管中的压力脉动高于主管道中的压力脉动,且属于该支管声共振频率范围内的谐波成分具有明显的振幅。支管的声共振频率不受主管道的影响。压力脉动随转速和背压的变化而变化,与背压相比,转速对脉动水平的影响更为明显。将安全阀支管和膨胀管串联的改造方案可有效降低主管道和支管道的压力脉动水平。
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Analyses of gas pulsation characteristics in the discharge pipeline of a hyper compressor
For the analysis of gas pulsation characteristics in the pipeline systems of low density polyethylene (LDPE) hyper compressors, a time-domain calculation method for compressor pipeline gas pulsation based on real gas properties is proposed. First the thermophysical property tables are prepared with gas state parameters as independent and dependent variables. Then one-dimensional unsteady flow equations and characteristic equations for pipeline flow are established based on real gas properties. After setting pipeline parameters and boundary conditions, the flow equations are discretized using a two-step method at the inner points of the pipeline. The characteristic equations are discretized using the trapezoidal integration method at the boundary points. Thus, the time-domain solving of pulsating flow field in the pipeline is realized. A self-developed numerical code was used to conduct the time-domain calculation and analysis of gas pulsation in the discharge pipeline of a two-stage hyper compressor. The calculated pressure pulsation curves based on real gas properties are in good agreement with experimental data, with a maximum difference lower than 4% of the local average pressure, which is smaller than the difference between the results calculated based on the plane wave theory and the measured data. The analysis of gas pulsation characteristics shows that the pressure pulsation in the main pipeline is mainly contributed by the fundamental and second harmonics. The pressure pulsation in the safety valve branch is higher than that in the main pipeline, and the harmonic components falling into the acoustic resonance frequency range of this branch have significant amplitudes. The acoustic resonance frequency of the branch pipeline is not affected by the main pipeline. Pressure pulsation varies with changes in rotational speed and back pressure, and the pulsation level is more significantly affected by rotational speed compared to back pressure. The renovation scheme of connecting the safety valve branch and expansion tube in series can effectively reduce the pressure pulsation levels of the main pipeline and branch pipeline.
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来源期刊
CiteScore
3.80
自引率
16.70%
发文量
370
审稿时长
6 months
期刊介绍: The Journal of Process Mechanical Engineering publishes high-quality, peer-reviewed papers covering a broad area of mechanical engineering activities associated with the design and operation of process equipment.
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