logging in or signing up 4 stroke heat engine swee77 Download Post to : URL : Related Presentations : Let's Connect Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Copy embed code: Embed: Flash iPad Dynamic Copy Does not support media & animations Automatically changes to Flash or non-Flash embed WordPress Embed Customize Embed URL: Copy Thumbnail: Copy The presentation is successfully added In Your Favorites. Views: 5161 Category: Education License: All Rights Reserved Like it (1) Dislike it (0) Added: May 29, 2012 This Presentation is Public Favorites: 11 Presentation Description No description available. Comments Posting comment... By: swee77 (15 month(s) ago) thank you trine Saving..... Post Reply Close Saving..... Edit Comment Close By: trineshd (18 month(s) ago) Nicely framed out with excellent animation and pictures. Loved it. Hats off to the author Saving..... Post Reply Close Saving..... Edit Comment Close By: emanoj2000 (22 month(s) ago) ur presentation r very good .i want a copy Saving..... Post Reply Close Saving..... Edit Comment Close Premium member Presentation Transcript HEAT ENGINE: 1 HEAT ENGINE Presented By, Engr.Prof.Dr.Muhammad Rizwan Chairman Mechanical Engineering Department NTU Faisalabad 03007660755 email@example.com Heat Engine and Energy Conversion: 2 Heat Engine and Energy Conversion Engines take heat energy and convert it into mechanical energy. Motors take electrical energy and convert it into mechanical energy. Basic Parts of the Gasoline Engine: 3 Basic Parts of the Gasoline Engine Cylinder block Piston Piston rings Piston pin Connecting rod Crankshaft Cylinder head Intake valve Exhaust valve Camshaft Timing gears Spark plug Cylinder Block: 4 Cylinder Block Basic frame of gasoline engine. Contains the cylinder. Piston: 5 Piston A sliding plug that harnesses the force of the burning gases in the cylinder. Piston Rings: 6 Piston Rings The rings seal the compression gases above the piston keep the oil below the piston rings. Piston Pins: 7 Piston Pins Also known as the wrist pin, it connects the piston to the small end of the connecting rod. It transfers the force and allows the rod to swing back and forth. Connecting Rod: 8 Connecting Rod Connects the piston and piston pin to the crankshaft. Crankshaft: 9 Crankshaft Along the the piston pin and connecting rod it converts the up and down motion (reciprocating) of the engine to spinning (rotary) motion. V Crank VS W Crank: 10 V Crank VS W Crank Flywheel: 11 Flywheel Carries the inertia when there is no power stroke. Lower End Action: 12 Lower End Action Cylinder Head: 13 Cylinder Head Forms the top of the combustion chamber. Contains the valves, the passageways for the fuel mixture to move in and out of the engine. W Head: 14 W Head Intake and Exhaust Valves: 15 Intake and Exhaust Valves Doorway that lets the gases in and out of the engine. Camshaft: 16 Camshaft Through the use of an eccentric the cam lobes push the valves open. The valve springs close them. Timing Gears: 17 Timing Gears These gears drive the camshaft from the crankshaft. Spark Plug: 18 Spark Plug Electric match used to begin the combustion process of burning air and gasoline to create heat. Engine Related Terms: 19 Engine Related Terms TDC (top dead center) BDC (bottom dead center) Stroke Bore Revolution Compression Ratio Displacement Cycle Intake Stroke: 20 Intake Stroke Intake valve opens. Piston moves down, ½ turn of crankshaft. A vacuum is created in the cylinder. Atmospheric pressure pushes the air/fuel mixture into the cylinder. Compression Stroke: 21 Compression Stroke Valves close. Piston moves up, ½ turn of crankshaft. Air/fuel mixture is compressed. Fuel starts to vaporize and heat begins to build. Power Stroke: 22 Power Stroke Valves remain closed. Spark plug fires igniting fuel mixture. Piston moves down, ½ turn of crankshaft. Heat is converted to mechanical energy. Exhaust Stroke: 23 Exhaust Stroke Exhaust valve opens. Piston move up, crankshaft makes ½ turn. Exhaust gases are pushed out polluting the atmosphere. Four Stroke Cycle Animation: 24 Four Stroke Cycle Animation Two Stroke Animation: 25 Two Stroke Animation Rotary Engine: 26 Rotary Engine Diesel Animation : 27 Diesel Animation Diesel 2 stroke: 28 Diesel 2 stroke Diesel: 29 Diesel Why not diesel?: 30 Why not diesel? Diesel engines, because they have much higher compression ratios (20:1 for a typical diesel vs. 8:1 for a typical gasoline engine), tend to be heavier than an equivalent gasoline engine. Diesel engines also tend to be more expensive. Why not diesel?: 31 Why not diesel? 3. Diesel engines, because of the weight and compression ratio, tend to have lower maximum RPM ranges than gasoline engines (see Question 381 for details). This makes diesel engines high torque rather than high horsepower, and that tends to make diesel cars slow in terms of acceleration. 4. Diesel engines must be fuel injected, and in the past fuel injection was expensive and less reliable Why not diesel?: 32 Why not diesel? 5. Diesel engines tend to produce more smoke and "smell funny". 6. Diesel engines are harder to start in cold weather, and if they contain glow plugs, diesel engines can require you to wait before starting the engine so the glow plugs can heat up. 7. Diesel engines are much noisier and tend to vibrate. 8. Diesel fuel is less readily available than gasoline Why not diesel?: 33 Why not diesel? One or two of these disadvantages would be OK, but a group of disadvantages this large is a big deterrent for lots of people. Advantages: 34 Advantages The two things working in favor of diesel engines are better fuel economy and longer engine life. Both of these advantages mean that, over the life of the engine, you will tend to save money with a diesel. However, you also have to take the initial high cost of the engine into account. You have to own and operate a diesel engine for a fairly long time before the fuel economy overcomes the increased purchase price of the engine. The equation works great in a big diesel tractor-trailer rig that is running 400 miles every day, but it is not nearly so beneficial in a passenger car. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.