ME 200 L35 Ground Transportation (Air Standard Otto Cycle) 9.1 and 9.2 Material not picked up this week may be recycled! ME 200 L35 Ground Transportation.

Slides:

Advertisements

Similar presentations

ME 200 L39 Vapor Compression Cycle Read 10

Advertisements

ME 200 L36 Ground Transportation (Continued) (Air Standard Otto Cycle) 9.1 and 9.2 Kim See’s Office ME Gatewood Wing Room 2172 Examination and Quiz grades.

ME 200 L38 CARNOT REFRIGERATION CYCLE Read 10.1 Material not picked up this week may be recycled! ME 200 L38 CARNOT REFRIGERATION CYCLE Read 10.1 Kim Sees.

\ ME 200 L34 Self Study Assignment 9.6 Todays Class 9.11 Material not picked up this week may be recycled! \ ME 200 L34 Gas Turbine Power Generation and.

ME 200 L19: ME 200 L19:Conservation Laws: Cycles HW 7 Due Wednesday before 4 pm HW 8 Posted Start early Kim See’s Office ME Gatewood Wing Room

EGR 334 Thermodynamics Chapter 9: Sections 3-4 Lecture 32: Gas Power Systems: The Diesel Cycle Quiz Today?

Material not picked up this week may be recycled! ME 200 L37: Aircraft Propulsion Reading Assignment 9.11 Office ME Gatewood Wing Room 2172 Material not.

THERMAL ENGINEERING (ME 2301 )

Problem Ideal and Actual Gas-Turbine (Brayton) Cycles 9–73

This Week > POWER CYCLES

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 28 Internal Combustion Engine Models The Otto Cycle The Diesel.

ME 200 L6: Energy Rate Balance, Transient Operation, Cyclic Repetitive Operation, Cycle Analysis, Efficiency & Coefficient of Performance Spring 2014.

İsmail ALTIN, PhD Assistant Professor Karadeniz Technical University Faculty of Marine Sciences Department of Naval Architecture and Marine Engineering.

GAS POWER CYCLES Chapter 9. Introduction Two important areas of application for thermodynamics are power generation and refrigeration. Two important areas.

THE CARNOT CYCLE AND ITS VALUE IN ENGINEERING The Carnot cycle is composed of four totally reversible processes: isothermal heat addition, isentropic.

EGR 334 Thermodynamics Chapter 9: Sections 1-2

Second Law of Thermodynamics Physics 202 Professor Lee Carkner Lecture 18.

Second Law of Thermodynamics Physics 202 Professor Lee Carkner Lecture 18.

Diesel / Brayton Cycles

Quiz Twelve Solutions and Review for Final Examination

Thermo & Stat Mech - Spring 2006 Class 6 1 Thermodynamics and Statistical Mechanics Entropy and the Second Law of Thermodynamics.

Thermodynamic Analysis of Internal Combustion Engines P M V SUBBARAO Professor Mechanical Engineering Department IIT Delhi Work on A Blue Print Before.

For next time: Read: § 8-6 to 8-7 HW11 due Wednesday, November 12, 2003 Outline: Isentropic efficiency Air standard cycle Otto cycle Important points:

MAE431-Energy System Presentation

Gas Power Cycle - Internal Combustion Engine

Engines, Motors, Turbines and Power Plants: an Overview Presentation for EGN 1002 Engineering Orientation.

INTERNAL COMBUSTION ENGINES (reciprocating). Geometry.

Applied Thermodynamics

Thermodynamic Cycles Air-standard analysis is a simplification of the real cycle that includes the following assumptions: 1) Working fluid consists of.

ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 27 Gas Power Generation The Brayton Cycle.

EGR 334 Thermodynamics Chapter 9: Sections 5-6

EGR 334 Thermodynamics Chapter 8: Sections 1-2

Thermodynamic Cycles for CI engines In early CI engines the fuel was injected when the piston reached TC and thus combustion lasted well into the expansion.

ME 200 L13: Energy Applications: Stationary; Energy Applications: Transportation ME 200 L13: Energy Applications: Stationary; Energy Applications: Transportation.

ME 200 L14: ME 200 L14:Conservation of Mass: Control Volume HW 5 cancelled HW 6 assigned Spring 2014 MWF.

8 CHAPTER Gas Power Cycles.

Gas Power Cycles.

ME 200 L18: ME 200 L18:Conservation Laws: Heat Exchangers HW 7 Posted Due in One Week: Kim See’s Office ME Gatewood Wing Room

Unit 4 Exercise – Gas Vapour and Combined Power Cycle

Chapter 9 Gas Power Systems.

\ ME 200 L32 Today’s Class 8.3 Exams not picked up this week may be recycled! \ ME 200 L32 Utility Power Generation Self Study Assignment 8.2 Today’s Class.

ME 200 L31: Review for Examination 3 ME 200 L31: Review for Examination 3 Thu 4/10/14 Examination 3 (L22 – L30) 6:30 – 7:30 PM WTHR 200, CL50 224, PHY.

Thermodynamic Cycles for CI engines

TEKNIK PERMESINAN KAPAL II (Minggu – 3) LS 1329 ( 3 SKS) Jurusan Teknik Sistem Perkapalan ITS Surabaya.

ME 200 L15: ME 200 L15:Conservation of Energy: Control Volumes 2.5, HW 5 cancelled; HW 6 assigned: Due 02/26/14

Gas Power Cycles Thermodynamics Professor Lee Carkner Lecture 17.

ME 200 L16: ME 200 L16:Transient & Steady State Processes Read ThermoMentor © Program Launched Spring 2014 MWF.

Chapter 9 Gas Power Cycles Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 8th edition by Yunus A. Çengel and Michael.

MT 313 IC ENGINES LECTURE NO: 04 (24 Feb, 2014) Khurram Yahoo Group Address: ICE14.

Gas Turbines for Aircraft Propulsion. AIR CRAFT ENGINE The turbojet engine consists of three main sections: the diffuser, the gas generator, and the nozzle.

ME 200 L24: Definition of Entropy & Entropy as a Property Kim See’s Office ME Gatewood Wing Room 2172 Please check your HW and Examination Grades on Blackboard.

ME 200 L27: Control Volume Entropy Balance ME 200 L27: Control Volume Entropy Balance Kim See’s Office ME Gatewood Wing Room 2172 Please check your HW.

AR Thermodynamics I Fall 2004 Course # 59:009 Chapter 9, Section 2 Professor Ratner.

ME 200 L23: Clausius Inequality and Control Volume Example Problems Kim See’s Office ME Gatewood Wing Room 2172 Please check your HW Grades on Blackboard.

Engine Cycle Analysis. Air Standard Otto Cycle.

President UniversityErwin SitompulThermal Physics 9/1 Lecture 9 Thermal Physics Dr.-Ing. Erwin Sitompul President University

APPLIED THERMODYNAMICS UNIT- 2 Gas power cycle 1 Department of Mechanical Engineering,A.I.E.T.,Mijar 3)Air Standard Diesel Cycle/ Constant Pressure cycle:

ME 200 L28: Control Mass Entropy Balance and Directionality of Processes ME 200 L28: Control Mass Entropy Balance and Directionality of Processes

8. GAS POWER CYCLES. Objectives Evaluate the performance of gas power cycles for which the working fluid remains a gas throughout the entire cycle. Develop.

Prepared by, Brijrajsinh Sarvaiya(13ME548) Jaypalsinh Jadeja(13ME517) Pradipsinh Jadeja(13ME518) Virendrasinh Parmar(13ME539) Gas power cycle.

ME 200 L26: Entropy Change for an Ideal Gas Kim See’s Office ME Gatewood Wing Room 2172 Please check your HW and Examination Grades on Blackboard Please.

THERMODYNAMIC ANALYSIS OF IC ENGINE Prepared by- Sudeesh kumar patel.

Gas Power Cycles.

Chapter: 08 POWER CYCLES.

Combustion and Power Generation Engineering Thermodynamics ( )

ES 211:Thermodynamics Tutorial 10

Gas Power Cycle - Internal Combustion Engine

Engineering Thermodynamics ME-103

Presentation transcript:

ME 200 L35 Ground Transportation (Air Standard Otto Cycle) 9.1 and 9.2 Material not picked up this week may be recycled! ME 200 L35 Ground Transportation (Air Standard Otto Cycle) 9.1 and 9.2 Kim See’s Office ME Gatewood Wing Room 2172 Examination and Quiz grades are available Blackboard Examinations and Quizzes can be picked up all of this week from Gatewood Room 2172 Material not picked up this week may be recycled! ThermoMentor © Program Spring 2014 MWF AM J. P. Gore Gatewood Wing 3166, Office Hours: MWF TAs: Robert Kapaku Dong Han

Stroke ►Compression ratio, r : volume at bottom dead center divided by volume at top dead center ► Displacement volume: volume swept by piston when it moves from top dead center to bottom dead center Top dead center Bottom dead center Introducing Engine Terminology

►The Otto cycle consists of four internally reversible processes in series: ►Process 1-2 : isentropic compression. ►Process 2-3 : constant-volume heat addition to the air from an external source. ►Process 3-4 : isentropic expansion. ►Process 4-1 : constant-volume heat transfer from the air. ►The Otto cycle compression ratio is: Air-Standard Otto Cycle

4 Air-Standard Otto Cycle: r is important! (1) Define Compression Ratio (2) Ideal Gas Law and eq. (1) (3) Isentropic compression (4) Combine (2) & (3) Compression Ratio is Very IMPORTANT!

►Ignoring kinetic and potential energy effects, closed system energy balances for the four processes of the Otto cycle reduce to give ►The thermal efficiency is the ratio of the net work to the heat added and for air standard cycle with constant specific heats, it reduces to solely a function of compression ratio:: Air-Standard Otto Cycle Compression Ratio is Very IMPORTANT!

6 ►Consider an Otto cycle with a compression ratio of 8.5 with constant specific heats, specific heats as a function of temperature, and compression and expansion with pv 1.2 = constant instead of the isentropic process. Find: (i) heat added, (ii) heat rejected, (iii) work done in the compression and expansion strokes, (iv) thermal efficiency, and (v) break mean effective pressure.

►Since the air-standard Otto cycle is composed of internally reversible processes, areas on the T-s and p- v diagrams can be interpreted as heat and work, respectively: ►On the T-s diagram, heat transfer per unit of mass is ∫Tds. Thus, Area 2-3-a-b-2 represents heat added per unit of mass. Area 1-4-a-b-1 is the heat rejected per unit of mass. The enclosed area is the net heat added, which equals the net work output. Air-Standard Otto Cycle

►On the p- v diagram, work per unit of mass is ∫pd v. Thus, Area 1-2-a-b-1 represents work input per unit of mass during the compression process. Area 3-4-b-a-3 is the work done per unit of mass in the expansion process. The enclosed area is the net work output, which equals the net heat added. Air-Standard Otto Cycle

►The compression ratio, r = V 2 /V 1, is an important operating parameter for reciprocating internal combustion engines as brought out by the following discussion centering on the T-s diagram: ►An increase in the compression ratio changes the cycle from to 1-2 ′ -3 ′ ►Since the average temperature of heat addition is greater in cycle 1-2 ′ -3 ′ -4-1, and both cycles have the same heat rejection process, cycle 1-2 ′ -3 ′ -4-1 has the greater thermal efficiency. ►Accordingly, the Otto cycle thermal efficiency increases as the compression ratio increases. Air-Standard Otto Cycle

10 ►Now consider an Otto cycle with a compression ratio of 12.5 with (a) constant specific heats, (b) specific heats as a function of temperature, and (c) compression and expansion with pv 1.2 = constant instead of the isentropic process. Find: (i) heat added (kJ/kg), (ii) heat rejected (kJ/kg), (iii) work done in the compression (kJ/kg) and expansion strokes (kJ/kg), (iv) thermal efficiency, and (v) break mean effective pressure.

11 ►Consider an Otto cycle with a compression ratio of 8.5 with constant specific heats, specific heats as a function of temperature, and compression and expansion with pv 1.2 = constant instead of the isentropic processes. Considering internal irreversibilities only, find: (I) Entropy change and (II) Entropy generation during each of the processes: 1-2, 2-3, 3-4, and 4-1.