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Research and clearance analysis on of steam twin-screw expander employed in indutrial waste heat recovery

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  • Zhao, Zhaorui
  • Zhang, Jingyu
  • Wang, Gaofeng
  • Yuan, Hao
  • Tian, Yafen

Abstract

In actual factories, screw expanders frequently operate under partial loads.To address the lack of theoretical research and the risks of errors in engineering design associated with steam pressure differential power generation under these conditions,a simulation of the twin-screw expander's working process was developed. The rotor profile was designed, geometric variables such as rotor mesh clearance were calculated, and models for leakage and heat transfer were established. A suction pressure correction model was proposed for the suction process under partial loads, along with correction parameters to simplify simulations.Experimental results demonstrate that the twin-screw expander operates stably under highly fluctuating conditions, demonstrating excellent variable load performance.As the load decreases, the loss of suction pressure reduces the expander's pressure differential, leading to lower leakage and improved efficiency. When the load is reduced from 100 % to 65 %, the volumetric efficiency increases from 78.87 % to 84.76 %, and the isentropic efficiency rises from 66.81 % to 74.25 %.Compared to experimental data, the flow calculation error of the suction pressure correction model presented in this study is controlled within 3 %.This model addresses performance calculations under partial loads, ensuring that theoretical models better align with real-world applications and supporting accurate selection of twin-screw expanders.This model enables appropriate selection of expanders to reduce pressure losses and enhance economic efficiency.

Suggested Citation

  • Zhao, Zhaorui & Zhang, Jingyu & Wang, Gaofeng & Yuan, Hao & Tian, Yafen, 2024. "Research and clearance analysis on of steam twin-screw expander employed in indutrial waste heat recovery," Energy, Elsevier, vol. 312(C).
    • Handle: RePEc:eee:energy:v:312:y:2024:i:c:s0360544224032158
    DOI: 10.1016/j.energy.2024.133439
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    References listed on IDEAS

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