swirl ratio as a function of piston geometry.Figure 6.22 Swirl ratio and squish versus crank angle. (Adapted from Belaire...Figure 6.23 Squish velocity and turbulent velocity as a function of piston g...Figure 6.24 Laser Doppler velocimetry (LDV) steady‐ flow test rig.Figure 6.25 CFD grid for in‐cylinder flow of a four‐ valve cylinder. (Courte...Figure 6.26 Close‐up of CFD grid. (Courtesy Adapco.)Figure 6.27 CFD flow field. (Courtesy Adapco.)
7 Chapter 7Figure 7.1 Laser shadowgraph of lean
= 0.55 (left) and rich
= 1.1 (right...Figure 7.2 Pressure profiles for Figure 7.1. (Adapted from Witze and Vilchis...Figure 7.3 Representative mass fraction burned curves.
For varying equival...Figure 7.4 Ignition delay versus equivalence ratio and residual fraction. (A...Figure 7.5 Combustion duration versus equivalence ratio and residual fractio...Figure 7.6 Effect of combustion chamber geometry on combustion duration and ...Figure 7.7 Temperature and species concentration profiles during flame propa...Figure 7.8 Dependence of laminar flame speed
on equivalence ratio
(
K, Figure 7.9 Dependence of laminar flame speed
on unburned gas temperature
Figure 7.10 Ink roller model of turbulent combustion.Figure 7.11 Pressure profiles for knocking conditions. (Adapted from Douaud ...Figure 7.12 Schlieren photographs of knock process. (Adapted from Smith et a...Figure 7.13 Temperature history of the end gas in Figure 7.12 as determined ...Figure 7.14 High‐speed photographic sequence of the luminosity of a diesel f...Figure 7.15 Simple model of diesel combustion.Figure 7.16 Detailed model of diesel combustion. (Adapted from Dec 1997.)Figure 7.17 Energy release profiles for short‐ and long‐duration fuel inject...Figure 7.18 The effective fuel injection rate versus crank angle. (Adapted f...Figure 7.19 Evolution of a fuel parcel from liquid fuel to combustion produc...Figure 7.20 Spray parcel entrainment and mixing.Figure 7.21 Instantaneous fractions of injected, vaporized, and burned fuel ...Figure 7.22 Predicted energy release versus crank angle for two different ch...Figure 7.23 Representative PPCI dual injection strategy.Figure 7.24 Representative RCCI dual fuel operation.Figure 7.25 Temperature and concentration profiles for
K (iso‐octane).Figure 7.26 Temperature and concentration profiles for
K (iso‐octane).Figure 7.27 Ignition delay as a function of initial temperature
and octane...
8 Chapter 8Figure 8.1 Mass fraction burned versus crank angle (Example 8.1).Figure 8.2 Pressure versus crank angle (Example 8.1).Figure 8.3 Calculated temperature of burned gas
and unburned gas
(Exampl...Figure 8.4 Predicted equilibrium and rate limited NO concentrations (Example...Figure 8.5 Predicted equilibrium and rate limited NO concentrations (Example...Figure 8.6 Calculated exhaust NO concentration versus equivalence ratio and ...Figure 8.7 NO concentration versus cylinder wall temperature (Example 8.1)....Figure 8.8 NO concentration versus start of heat release (Example 8.1).Figure 8.9 NO concentration versus engine speed (Example 8.1).Figure 8.10 NO concentration versus IMEP (Example 8.1).Figure 8.11 Advanced timing increases NO. (Adapted from Huls and Nickol 1967...Figure 8.12 Ensemble of fluid elements during compression and combustion.Figure 8.13 Exhaust gas composition versus fuel–air ratio for supercharged e...Figure 8.14 CO concentration in two elements of the charge the burned at dif...Figure 8.15 Wall vortex formed by exhaust stroke. (Adapted from Tabaczynski ...Figure 8.16 Variation of HC concentration at the exhaust valve during the ex...Figure 8.17 HC concentrations as a function of load for direct injection and...Figure 8.18 Two‐ and three‐ring polycyclic aromatic hydrocarbon (PAH) struct...Figure 8.19 Soot formation and oxidation versus temperature (Example 8.2).Figure 8.20 Soot and
formation on a
diagram.Figure 8.21 Representative plot of soot and
tradeoff versus injection timi...Figure 8.22 Representative plot of soot and
tradeoff versus EGR.Figure 8.23 Engine emission control methods. (Courtesy Englehard Corporation...Figure 8.24 Catalytic converter. (Courtesy Englehard Corporation.)Figure 8.25 Catalytic converter components. (Courtesy Englehard Corporation....Figure 8.26 Conversion efficiencies for oxidizing catalysts. (Adapted from M...Figure 8.27 Conversion efficiencies for three‐way catalyst versus air–fuel r...Figure 8.28 Illustration for Homework Problem 8.3.Figure 8.29 Illustration for Homework Problem 8.14.
9 Chapter 9Figure 9.1 Distillation process.Figure 9.2 (a) Paraffins, (b) Olefins, and (c) Naphthenes.Figure 9.3 Aromatics.Figure 9.4 (a) Alcohols, (b) Ethers, and (c) Nitroparaffins.Figure 9.5 Specific heat of various hydrocarbons.Figure 9.6 Specific heat of various hydrocarbons.Figure 9.7 Effect of fuel–air ratio on knock‐limited imep for three aircraft...Figure 9.8 Effect of fuel structure on the detonation tendency of paraffinic...Figure 9.9 Cetane and octane number correlation for hydrocarbon fuels. (Adap...
10 Chapter 10Figure 10.1 Stribeck diagram showing friction regimes.Figure 10.2 Schematic of lubricant film thickness vs. Stribeck duty paramete...Figure 10.3 Metal‐to‐metal contact in boundary lubrication. Adapted from Ros...Figure 10.4 Dynamic viscosity versus temperature for various oil SAE grades....Figure 10.5 Diesel engine fmep versus piston speed. (Adapted from Brown 1973...Figure 10.6 Motored friction mean effective pressure (fmep) during disassemb...Figure 10.7 Gasoline engine friction versus load. (Adapted from Gish 1957.)...Figure 10.8 Piston and connecting rod. (Courtesy Mahle, Inc.)Figure 10.9 Piston head for a spark‐ignition engine. (Courtesy Mahle, Inc.)...Figure 10.10 Piston ring assembly schematic. (Adapted from Merrion 1994.)Figure 10.11 Common types of piston rings.Figure 10.12 Piston and ring friction,
= 4.57 m/s, bmep = 5.78 bar,
=
...Figure 10.13 Friction of piston skirt, rings, and gas pressure.Figure 10.14 Essential features of a hydrodynamic analysis of ring friction....Figure 10.15 Taper compression ring geometry.Figure 10.16 Barrel compression ring geometry.Figure 10.17 Oil film pressure and thickness for a taper compression ring (E...Figure 10.18 Oil film pressure and thickness for a barrel compression ring (...Figure 10.19 Effect of load on minimum oil film thickness. (Adapted from All...Figure 10.20 Piston force balance.Figure 10.21 Piston side thrust load and the switch of contact sides. (Adapt...Figure 10.22 Engine crankshaft. (Courtesy Norton Manufacturing.)Figure 10.23 Journal bearing geometry.Figure 10.24 Journal bearing pressure and film thickness profiles (Example 1...Figure 10.25 Various valve train designs. (Adapted from Rosenberg 1982.)Figure 10.26 Representative V8 engine camshaft. (Courtesy COMP Cams.)Figure 10.27 Type V push rod rocker arm with roller follower. (Courtesy Jese...Figure 10.28 Rocker arms on cylinder head. (Courtesy Jesel Valvetrain Compon...Figure 10.29 Engine poppet valves. (Courtesy Wesco Valve.)Figure 10.30 Engine oil pump. (Courtesy Melling Engine Parts).Figure 10.31 Engine water pump. (Courtesy Airtex Products).Figure 10.32 Friction mean effective pressure versus engine speed.Figure 10.33 Relative contributions of fmep components versus engine speed....
11 Chapter 11Figure 11.1 Liquid‐cooling system schematic.Figure 11.2 Air‐cooling system schematic.Figure 11.3 Engine instrumented for energy balance measurements.Figure
