Presentation is loading. Please wait.

Presentation is loading. Please wait.

Measuring Engine Performance ME 115 Laboratory Spring 2008.

Published byIlene Long Modified over 9 years ago

Similar presentations

Presentation on theme: "Measuring Engine Performance ME 115 Laboratory Spring 2008."— Presentation transcript:

1 Measuring Engine Performance ME 115 Laboratory Spring 2008

2 Otto Cycle Review Cengel & Boles, Thermodynamics: An Engineering Approach, 2006.

3 Common terms used to compare engine performance Brake power (bp): net power output of an IC engine Torque: A force acting through a radius RPM: engine speed, in rotations per minute Specific fuel consumption (sfc): rate of fuel consumption per unit of brake power

4 Mean Effective Pressure MEP: a fictitious pressure that, if acted on the piston during the entire power stroke, would produce the same amount of net work as that produced during the actual cycle (Cengel & Boles, 2006) If the MEP goes up, the cylinder volume can go down and still achieve the same power output

5 Mean Effective Pressure, cont. Indicated MEP (imep): uses the total power output minus the power needed for the intake and exhaust stokes (indicated power) Brake MEP (bmep): the power used to overcome friction in the cylinder is also subtracted; this term is used more often than the imep

6 Brake Thermal Efficiency Brake thermal efficiency: brake power/rate of heat output for complete combustion Brake thermal efficiency=indicated thermal efficiency* mechanical efficiency Mechanical efficiency: related to the amount of power used to overcome friction

7 Carnot Efficiency To see how well our engine is doing, we can compare our brake thermal efficiency to the Carnot efficiency Remember that the Carnot efficiency is the best we can do!   =1-(T low /T high ), where T’s are in absolute scale  We could estimate T high as our exhaust temperature  T low is our ambient temperature

8 Engine Irreversibilities Heat transfer from the cylinder wall during compression: will this irreversibility be larger for slow or fast engine speeds? Pressure losses across the valves: will this irreversibility be larger for slow or fast engine speeds? Frictional work due to sliding ring seals and other rotating components: will this irreversibility be larger for slow or fast engine speeds?

9 Energy Efficiency Variation with Engine Speed Decher, 1994, Energy Conversion: Systems, Flow Physics and Engineering.

Download ppt "Measuring Engine Performance ME 115 Laboratory Spring 2008."

Similar presentations

Engine Parameters.

Engine Parameters.
Thermodynamics AP Physics Chapter 15.

Thermodynamics AP Physics Chapter 15.
Chapter 3 Engine Operation

Chapter 3 Engine Operation
Engine Geometry BC L TC l VC s a q B

Engine Geometry BC L TC l VC s a q B
Engine Terminology Engine Measurement Lesson 8 March 2008.

Engine Terminology Engine Measurement Lesson 8 March 2008.
Lab T1: Compression Ignition (Diesel) Engine Lab Instructor: M

Lab T1: Compression Ignition (Diesel) Engine Lab Instructor: M
STUDENT NAME: (1) Patel Vidhi A.

STUDENT NAME: (1) Patel Vidhi A.
THERMAL ENGINEERING (ME 2301 )

THERMAL ENGINEERING (ME 2301 )
Conceptual & Thermodynamic Description of Expansion in I.C. Engine P M V Subbarao Professor Mechanical Engineering Department The Actual & Useful Extent.

Conceptual & Thermodynamic Description of Expansion in I.C. Engine P M V Subbarao Professor Mechanical Engineering Department The Actual & Useful Extent.
Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 28 Internal Combustion Engine Models The Otto Cycle The Diesel.

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 28 Internal Combustion Engine Models The Otto Cycle The Diesel.
Effect of Piston Dwell on Engine Performance P M V Subbarao Professor Mechanical Engineering Department Sufficiency of time to Execute a Process…..

Effect of Piston Dwell on Engine Performance P M V Subbarao Professor Mechanical Engineering Department Sufficiency of time to Execute a Process…..
Internal Combustion Engine Theory

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

GAS POWER CYCLES Chapter 9. Introduction Two important areas of application for thermodynamics are power generation and refrigeration. Two important areas.
Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 25 Comparison to Carnot’s Heat Engine Effects of Boiling and.

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lecture 25 Comparison to Carnot’s Heat Engine Effects of Boiling and.
Lesson 3: Reciprocating Engine Theory Of Operation

Lesson 3: Reciprocating Engine Theory Of Operation
I.C. ENGINES Practical No: 5 (22 Apr, 2014). Indicated Power P i Date Definition of P i Is the actual power developed by the engine Burning of fuel (

I.C. ENGINES Practical No: 5 (22 Apr, 2014). Indicated Power P i Date Definition of P i Is the actual power developed by the engine Burning of fuel (
Diesel Engine Classification

Diesel Engine Classification
Pre-test Study Guide Thermodynamics Laws Q=m C ∆T Q = m L P V = n R T ∆U = Q – W Effic. = T h -T c /T c Other Laws W = F * d P = W / t P = F / A Vocabulary.

Pre-test Study Guide Thermodynamics Laws Q=m C ∆T Q = m L P V = n R T ∆U = Q – W Effic. = T h -T c /T c Other Laws W = F * d P = W / t P = F / A Vocabulary.
© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only Publisher The Goodheart-Willcox Co., Inc. Tinley Park, Illinois.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only Publisher The Goodheart-Willcox Co., Inc. Tinley Park, Illinois.
Internal Combustion Engines. Ideal Diesel Cycle Ideal Diesel Cycle.

Internal Combustion Engines. Ideal Diesel Cycle Ideal Diesel Cycle.

Similar presentations

Ads by Google