Subjects
Applied Mathematics for Electrical Engineering - 3130908
Complex Variables and Partial Differential Equations - 3130005
Engineering Graphics and Design - 3110013
Basic Electronics - 3110016
Mathematics-II - 3110015
Basic Civil Engineering - 3110004
Physics Group - II - 3110018
Basic Electrical Engineering - 3110005
Basic Mechanical Engineering - 3110006
Programming for Problem Solving - 3110003
Physics Group - I - 3110011
Mathematics-I - 3110014
English - 3110002
Environmental Science - 3110007
Software Engineering - 2160701
Data Structure - 2130702
Database Management Systems - 2130703
Operating System - 2140702
Advanced Java - 2160707
Compiler Design - 2170701
Data Mining And Business Intelligence - 2170715
Information And Network Security - 2170709
Mobile Computing And Wireless Communication - 2170710
Theory Of Computation - 2160704
Semester
Semester - 1
Semester - 2
Semester - 3
Semester - 4
Semester - 5
Semester - 6
Semester - 7
Semester - 8
Basic Mechanical Engineering
(3110006)
BME-3110006
Description and thermal efficiency of Carnot; Rankine; Otto cycle and Diesel cycles
BE | Semester
1
Topic : Description and thermal efficiency of Carnot; Rankine; Otto cycle and Diesel cycles
BE - Semester -
Summer - 2019
-
04-06-2023
Total Marks :
70
Q3
(b)
Summer-2019
Derive the equation for efficiency of Carnot cycle.
4 Marks
Unit : Heat Engines
Q3
(b)
Summer-2020
The efficiency of Otto cycle is a function of compression ratio: Prove it.
4 Marks
Unit : Heat Engines
Q4
(c)
Summer-2019
In an ideal Otto cycle the air at the beginning of isentropic compression is at 1 bar and 15oC. The ratio of compression is 8. If the heat added during the constant volume process is 1000 kJ/kg, determine (a) the maximum temperature in the cycle, (b) the air standards efficiency (C) work done per kg of air.
7 Marks
Unit : Heat Engines
