Identifying the influence of inlet velocity changes to pressure drop and collecting efficiency in Stairmand and Lapple type cyclone separators

Authors

DOI:

https://doi.org/10.15587/1729-4061.2024.310565

Keywords:

cyclone separator, pressure drop, collecting efficiency, Stairmand and Lapple type

Abstract

The object of this research is to compare the performance of Stairmand and Lapple type cyclone separators. The main problem to be solved in this research is determining which Stairmand or Lapple type cyclone separator is more suitable for integration into the pyrolysis system. The comparison is based on key performance indicators: pressure drop and collecting efficiency. The research findings indicate that both Stairmand and Lapple cyclone separators exhibit similar trends in pressure drop and collecting efficiency. As inlet velocity increases, the pressure drop also increases for both types. However, the collecting efficiency initially rises but then declines when inlet velocities exceed 13 m/s. The Lapple variant achieved a peak collecting efficiency of 98.94 % and pressure drop 16.26 mbar at an inlet velocity of 13 m/s, whereas the Stairmand design reached 97.33 % and pressure drop 12.16 mbar at 13 m/s inlet velocity. The Lapple type cyclone separator outperformed the Stairmand type in terms of both of pressure drop and collecting efficiency. This superiority is attributed to the specific design features and characteristics of the Lapple type. The superior performance of the Lapple type cyclone separator can be explained by its unique design elements that contribute to improved particulate matter separation and pressure drop. These elements may include differences in cylinder height and particulate matter outlet diameter. Based on the findings of this research, the Lapple type cyclone separator is recommended for integration into pyrolysis systems. However, it is important to consider the specific operating conditions of the pyrolysis process, such as temperature, the particulate matter size distribution, flow rate, and desired separation efficiency

Supporting Agency

  • Authors would like to thank the Center for Research and Community Service, Politeknik Negeri Jakarta, Indonesia for funding this research through Hibah PRD.

Author Biographies

Adi Syuriadi, Politeknik Negeri Jakarta; Universitas Indonesia

Master of Engineering, Lecturer

Department of Mechanical Engineering

Department of Mechanical Engineering

Ahmad Indra Siswantara, Universitas Indonesia

Doctor of Engineering, Lecturer

Department of Mechanical Engineering

Ridho Irwansyah, Universitas Indonesia

Doctor of Engineering, Lecturer

Department of Mechanical Engineering

Supriyadi Supriyadi, Politeknik Negeri Jakarta

Student of Power Plant Study Program

Department of Mechanical Engineering

Candra Damis Widiawaty, Politeknik Negeri Jakarta

Doctor of Engineering, Lecturer

Department of Mechanical Engineering

Muhammad Hilman Gumelar Syafei, Universitas Negeri Semarang

Magister of Engineering, Lecturer

Department of Mechanical Engineering

Illa Rizianiza, Institut Teknologi Kalimantan

Magister of Engineering, Lecturer

Department of Mechanical Engineering

Sulaksana Permana, Gunadarma University; Universitas Indonesia

Doctor of Engineering in Metallurgy and Materials, Assistance Professor

Department of Mechanical Engineering

Department of Metallurgy and Materials

Iwan Susanto, Politeknik Negeri Jakarta

Doctor of Materials Science and Engineering, Associate Professor

Master's Program in Applied Manufacturing Technology Engineering

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Identifying the influence of inlet velocity changes to pressure drop and collecting efficiency in Stairmand and Lapple type cyclone separators

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Published

2024-08-30

How to Cite

Syuriadi, A., Siswantara, A. I., Irwansyah, R., Supriyadi, S., Widiawaty, C. D., Syafei, M. H. G., Rizianiza, I., Permana, S., & Susanto, I. (2024). Identifying the influence of inlet velocity changes to pressure drop and collecting efficiency in Stairmand and Lapple type cyclone separators. Eastern-European Journal of Enterprise Technologies, 4(6 (130), 22–28. https://doi.org/10.15587/1729-4061.2024.310565

Issue

Vol. 4 No. 6 (130) (2024): Technology organic and inorganic substances

Section

Technology organic and inorganic substances

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Copyright (c) 2024 Adi Syuriadi, Ahmad Indra Siswantara, Ridho Irwansyah, Supriyadi Supriyadi, Candra Damis Widiawaty, Muhammad Hilman Gumelar Syafei, Illa Rizianiza, Sulaksana Permana, Iwan Susanto

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