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An applicable approach to mitigate pressure rise rate in an HCCI engine with negative valve overlap

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  • Hunicz, Jacek
  • Mikulski, Maciej
  • Geca, Michal S.
  • Rybak, Arkadiusz

Abstract

Low-temperature combustion in a homogeneous-charge compression-ignition (HCCI) engine offers high thermal efficiency while cutting off emissions. However, HCCI’s feasibility is hampered by excessive peak pressure rise rates under high load, causing combustion noise and possible engine damage. This study considers extending the high-load limit in a boosted HCCI engine accommodating variable valve timing and fuel reforming during negative valve overlap. Three techniques are evaluated on a research engine: (i) exhaust valve timing retardation (ii) boost pressure adjustment and (iii) reduction of fuel subjected to reforming. Two load regimes are explored: a mid-load point with indicated mean effective pressure of 0.61 MPa; and high-load conditions achieved by 25% more fuelling. The former is often reported as boundary condition for HCCI’s, the latter is usually far beyond the acceptable pressure rise rate limit. Results indicate that strategies (i) and (iii) offer a trade-off-free solution for high-load extension. This can be realized as a supervisory, in-cylinder pressure based, control function. Independently of the pressure rise rate mitigation method considered, two key variables are crucial for closed-loop control: the in-cylinder volume at 50% fuel burnt and the combustion duration. They are closely coupled and can be real-time calculated using well-established control framework based on sensing the combustion timing. The expansion rate and differences in fuel mass subjected to reforming are secondary for pressure rise rate estimation and should be considered if greater accuracy is required.

Suggested Citation

  • Hunicz, Jacek & Mikulski, Maciej & Geca, Michal S. & Rybak, Arkadiusz, 2020. "An applicable approach to mitigate pressure rise rate in an HCCI engine with negative valve overlap," Applied Energy, Elsevier, vol. 257(C).
    • Handle: RePEc:eee:appene:v:257:y:2020:i:c:s0306261919317052
    DOI: 10.1016/j.apenergy.2019.114018
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    References listed on IDEAS

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    Cited by:

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    3. Atakan, Burak & Kaiser, Sebastian A. & Herzler, Jürgen & Porras, Sylvia & Banke, Kai & Deutschmann, Olaf & Kasper, Tina & Fikri, Mustapha & Schießl, Robert & Schröder, Dominik & Rudolph, Charlotte & K, 2020. "Flexible energy conversion and storage via high-temperature gas-phase reactions: The piston engine as a polygeneration reactor," Renewable and Sustainable Energy Reviews, Elsevier, vol. 133(C).
    4. Koszalka, Grzegorz & Hunicz, Jacek, 2021. "Comparative study of energy losses related to the ring pack operation in homogeneous charge compression ignition and spark ignition combustion," Energy, Elsevier, vol. 235(C).
    5. Moradi, Jamshid & Gharehghani, Ayat & Mirsalim, Mostafa, 2020. "Numerical investigation on the effect of oxygen in combustion characteristics and to extend low load operating range of a natural-gas HCCI engine," Applied Energy, Elsevier, vol. 276(C).
    6. Hunicz, Jacek & Mikulski, Maciej & Koszałka, Grzegorz & Ignaciuk, Piotr, 2020. "Detailed analysis of combustion stability in a spark-assisted compression ignition engine under nearly stoichiometric and heavy EGR conditions," Applied Energy, Elsevier, vol. 280(C).

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