1 / 29

C OMBUSTION E NGINEERING

C OMBUSTION E NGINEERING. P ROF . S EUNG W OOK B AEK D IV . OF A EROSPACE E NGINEERING , KAIST, IN KOREA R OOM : 3304 T ELEPHONE : 3714. P HYSICAL P ICTURE OF C OMBUSTION WAVE. V ERY S MALL I GNITION E NERGY – E XTINGUISHED

vernon
Télécharger la présentation

C OMBUSTION E NGINEERING

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. COMBUSTION ENGINEERING PROF. SEUNG WOOK BAEK DIV.OFAEROSPACE ENGINEERING, KAIST, IN KOREA ROOM : 3304 TELEPHONE : 3714

  2. PHYSICAL PICTURE OF COMBUSTION WAVE VERY SMALL IGNITION ENERGY – EXTINGUISHED Vs = SPACE VELOCITY OF THE FLAME ; I.E. RELATIVE TO WALL Vu = VELOCITY OF UNBURNED MIXTURE RELATIVE TO WALL Vf= VELOCITY OF THE FLAME RELATIVE TO THE UNBURNED MIXTURE Vf = Vs –Vu :BURNING VELOCITY PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  3. INSTANTANEOUS GENERATION OF A C-JDETONATION VCJ U = 0 Vc P(x) Vc STAGNANT BURNED GAS V(x) P1 PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  4. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  5. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  6. STRUCTURE OF THE DETONATION WAVE INDUCTION ZONE 2S UNBURNED COMBUSTION V2 VCJ CJ (2) IGNITION DELAY TIME P1 T2 P2S VCJ T2S PCJ T1 V2 P1 V2S PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  7. USUALLY GET Chapman-JouguetDETONATION ; PROPERTIES OF C-JDETONATION MASS-MOMENTUM-ENERGY FOR C-JWAVES AND PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  8. VALID FOR C-JDETONATION OR DEFLAGRATION PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  9. FOR DETONATION, OR OR OR PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  10. C-J DETONATION VELOCITY DEPENDS ONLY ON THE HEAT RELEASE Q, INDEPENDENT OF . THEREFORE, VARIES WITH ONLY BECAUSE THE SPEED OF SOUND CHANGES. PRESSURE RATIO, OR PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  11. FROM MASS, MOMENTUM, AND ENERGY OR OR PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  12. MACH NUMBER OF BURNED GASES RELATIVE TO THE WALLS FOR C-J (HIGH SUBSONIC) PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  13. COMPARISON BETWEEN PRESSURE BEHIND A SHOCK & C-JDETONATION FOR THE SAME MACH NUMBER Q 2S (1) PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  14. FOR C-JDEFLAGRATION, (GOOD FOR C-JDETONATION & DEFLAGRATION) FOR C-JDEFLGRATION, PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  15. GET (FOR C-JDETONATION) FOR DEFLAGRATION M= 1/6 EXAMPLE FOR THE C-JDETONATION OF MIXTURE PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  16. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  17. DIFFERNTIAL EQUATION OF TRANSPORT OF MATTER AND ENERGY INCLUDING COMBUSTION REAL COMBUSTION PHENOMENA INVOLVE HUNDREDS OF INTERACTING CHEMICAL REACTIONS. BUT FOCUS ATTENTION ON A MODEL OF COMBUSTION, WHICH ACCORDS WITH REALITY IN RESPECT OF THE OVERALL EFFECTS. PURPOSE : QUANTITATIVE PREDICTIONS OF COMBUSTION PHENOMENA PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  18. SIMPLE CHEMICALLY REACTING SYSTEM (SCRS) FUEL + OXIDANT PRODUCT 1 S 1+S S : STOICHIOMETRIC RATIO REACTANTS PRODUCE A UNIQUE PRODUCT IN FIXED PROPORTIONS BY MASS. INDEPENDENT OF TEMPERATURE PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  19. H : HEAT OF COMBUSTION IF AND PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  20. FOR STEADY 1-DDIFFUSION-CONTROLLED FLAMES THE FUEL AND OXIDIZER COMBINE WITH A FIXED STOICHIOMETRIC RATIO S : AND IF PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  21. OBEYS THE SAME DIFFERENTIAL EQUATION AS THE MASS FRACTION OF A CHEMICALLY INERT MATERIAL DOES. PRECISE KNOWLEDGE OF THE ‘S IS NOT NECESSARY. FOR SCRS • NO VISCOUS SHEAR WORK • NO KINETIC ENERGY EFFECTS • NO EXTERNAL ENERGY SOURCES PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  22. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  23. THE TWO STREAM MIXING PROCESS (AN IDEALIZATION OF COMBUSTION CHAMBER FLOWS) FOR ANY EXTENSIVE PROPERTY OF A FLUID WHICH IS FREE FROM SOURCES AND SINKS : CONSERVED PROPERTY : MIXTURE FRACTION PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  24. EX) min : MASS FRACTION OF AN INERT COMPONENT , , AND ANY LINEAR COMBINATION OF SUCH CONSERVED PROPERTIES: IF THE MIXING PROCESS IS ADIABATIC AND FREE FROM WORK INPUT, STAGNATION ENTHALPY IS A CONSERVED PROPERTY PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  25. THE FUEL AND OXIDANT MASS FRACTION ARE LINKED WITH IF F : FUEL, A : OXYGEN WITH DILUENT PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  26. AFTER CHEMICAL REACTION IS COMPLETED. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  27. PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

  28. IT SHOULD BE OBSERVED THAT THE MIXTURE FRACTION WILL OBEY THE SAME DIFFERENTIAL EQUATIONS AS DO AND . PROPULSION AND COMBUSTION LABORATORY COMBUSTION ENGINEERING

More Related