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Strategies to control combustion in HCCI engines: Modelling Investigations Ali M. Aldawood Supervisor: Dr Markus Kraft.

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Presentation on theme: "Strategies to control combustion in HCCI engines: Modelling Investigations Ali M. Aldawood Supervisor: Dr Markus Kraft."— Presentation transcript:

1 Strategies to control combustion in HCCI engines: Modelling Investigations Ali M. Aldawood Supervisor: Dr Markus Kraft

2 Ali M Aldawood ama44@cam.ac.uk HCCI Engine

3 Ali M Aldawood ama44@cam.ac.uk Control Problem in HCCI Engine Engine load Advance  Combustion start  Retard SOC

4 Ali M Aldawood ama44@cam.ac.uk Control Problem in HCCI Engine Engine load Advance  Combustion start  Retard Knocking limit Misfire area SOC

5 Ali M Aldawood ama44@cam.ac.uk Control Problem in HCCI Engine Engine load Upper load Lower load Advance  Combustion start  Retard Knocking limit Misfire area SOC Operating window

6 Ali M Aldawood ama44@cam.ac.uk Control Problem in HCCI Engine Engine load Advance  Combustion start  Retard Knocking limit Misfire area SOC Controlled timing

7 Ali M Aldawood ama44@cam.ac.uk  Investigate two fuel-based strategies to control the combustion timing  Detailed-chemistry, full-cycle model to simulate a single-cylinder HCCI engine  Closed-loop control of combustion timing using octane number or hydrogen ratio Purpose of Study Engine load Knocking limit Misfire area SOC Advance  Combustion start  Retard Controlled timing

8 Ali M Aldawood ama44@cam.ac.uk Sandia’s Cummins Diesel Engine Modelled Engine

9 Ali M Aldawood ama44@cam.ac.uk Coupling GT-Power with SRM Intake Compression Power Exhaust GT-Power Stochastic Reactor Model GT-Power Closed-Volume EV O 0 o 180 o 360 o 540 o 720 o Firing TDC IVC GT-Power simulates the open-volume (intake and exhaust) portion of the cycle SRM simulates the closed- volume (compression, combustion and expansion) portion of the cycle Pressure

10 Ali M Aldawood ama44@cam.ac.uk Octane Number & Hydrogen Control A closed-loop controller is integrated in the model. Either octane number or hydrogen ratio is varied to control the combustion phasing.

11 Ali M Aldawood ama44@cam.ac.uk Octane Number & Hydrogen Control A closed-loop controller is integrated in the model. Either octane number or hydrogen ratio is varied to control the combustion phasing.

12 Ali M Aldawood ama44@cam.ac.uk Hydrogen Addition – Load Transients Time (sec)

13 Ali M Aldawood ama44@cam.ac.uk Conclusion  Full-cycle HCCI engine model is integrated with Stochastic Reactor Model and closed-loop control  Integrated model provided effective tool to simulate HCCI transients and investigate combustion control strategies  Results suggest that both octane number and hydrogen addition are effective for HCCI combustion control

14 Ali M Aldawood ama44@cam.ac.uk End of Presentation Thank You

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