ESE 2021 - Civil Engineering ESE Topicwise Objective Solved Paper 1 by IES Master Publication

CIVIL ENGINEERING ESE TOPICWISE OBJECTIVE SOLVED PAPER-I

1995-2019

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IES MASTER PUBLICATION F-126, (Lower Basement), Katwaria Sarai, New Delhi-110016 Phone : 011-41013406, Mobile : 8130909220, 9711853908 E-mail : info.publications@iesmaster.org, info@iesmaster.org Web : iesmasterpublications.com, iesmaster.org

All rights reserved. Copyright ÂŠ 2019, by IES MASTER Publications. No part of this booklet may be reproduced, or distributed in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise or stored in a database or retrieval system without the prior permission of IES MASTER, New Delhi. Violates are liable to be legally prosecuted.

First Edition

: 2016

Second Edition : 2017 Third Edition

: 2018

Fourth Edition : 2019

Typeset at : IES Master Publication, New Delhi-110016

PREFACE

Engineering Services Examination is the gateway to an immensely satisfying job in the engineering sector of India that offers multi-faceted exposure. The exposure to challenges and opportunities of leading the diverse field of engineering has been the main reason behind engineering students opting for Engineering Services as compared to other career options. To facilitate selection into these services, availability of arithmetic solution to previous years’ paper is the need of the day. It is an immense pleasure to present previous years’ topic-wise objective solved papers of Engineering Services Examination (ESE). This book is an outcome of regular and detailed interaction with the students preparing for ESE every year. It includes solutions along with detailed explanation to all questions. The prime objective of bringing out this book is to provide explanation to each question in such a manner that just by going through the solutions, students will be able to understand the basic concepts and have the capability to apply these concepts in solving other questions that might be asked in future exams. Towards this end, this book becomes indispensable for every ESE aspiring candidate.

Mr. Kanchan Kumar Thakur Director–IES Master

CONTENT

Strength of Material ...................................................................................... 001 – 192

Structure Analysis ......................................................................................... 193 – 304

Steel Structure

RCC and Prestressed Concrete .................................................................... 411 – 526

PERT CPM

......................................................................................... 527 – 612

Building Material

......................................................................................... 613 – 710

......................................................................................... 305 – 410

UNIT-1

STRENGTH OF MATERIALS

SYLLABUS Elastic constants, stress, plane stress, Mohr’s circle of stress, strains, plane strain, Mohr’s circle of strain, combined stress, Elastic theories of failure; Simple bending, shear; Torsion of circular and rectangular sections and simple members.

CONTENTS

Strength of Materials .................................................................................. 01 – 32

Shear Force and Bending Moment ............................................................. 33 – 65

Deflection of Beams .................................................................................. 66 – 85

Transformation of Stress and Strain .......................................................... 86 – 110

Combined Stresses ................................................................................ 111 – 122

Bending Stress in Beams ...................................................................... 123 – 142

Shear Stress in Beams .......................................................................... 143 – 152

Torsion of Circular Shaft ......................................................................... 153 – 168

Columns ............................................................................................... 169 – 180

10.

Springs ................................................................................................. 181 – 184

11.

Thick and Thin Cylinder/Sphere .............................................................. 185 – 190

12.

Moment of Inertia .................................................................................... 191 – 192

(b)  x   (  y   z )

(d) 1/ε x  1/ε y  1/ε z

A solid metal bar of uniform diameter D and length L is hung vertically from a ceiling. If the density of the material of the bar is  and the modulus of elasticity is E, then the total elongation of the bar due to its own weight is

(d)

(b) 6 cc (d) 10–3 cc

In terms of bulk modulus (K) and modulus of rigidity (G), the Poisson’s ratio can be expressed as (a) (3K – 4G)/(6K+4G) (b) (3K+4G)/(6K– 4G) (c) (3K – 2G)/(6K+ 2G) (d) (3K+2G)/(6K – 4G)

2L2

Strain

A steel cube of volume 8000 cc is subjected to an all round stress of 1330 kg/sq. cm. The bulk modulus of the material is 1.33 × 106 kg/sq. cm. The volumetric change is (a) 8 cc (c) 0.8 cc

E

A rigid beam ABCD is hinged at D and supported by two springs at A and B as shown in the given figure. The beam carries a vertical load P at C. The stif f ness of spring at A is 2K and that of B is K. a

(d) Strain

(b) L2 / 2E

(a)  L / 2E

(c)

Strain Stress

x, y, z directions respectively and  is the Poisson’s ratio, the magnitude of unit volume change of the element is given by

Stress

Strain

plane stress;  x ,  y and  z are normal strains in

(a)  x   y  z

(b)

Stress

(a)

Given that f or an element in a body of homogeneous isotropic material subjected to

Stress

STRENGTH OF MATERIALS

IES-1995 1.

Civil Engineering

ESE Topicwise Objective Solved Paper-I 1995-2019

Two bars one of material A and the other of material B of same length are tightly secured between two unyielding walls. Coefficient of thermal expansion of bar A is more than that of B. When temperature rises the stresses induced are (a) tension in both materials

(b) tension in material A and compression in material B

The ratio of forces of spring at A and that of spring at B is (a) 1 (c) 3 4.

(b) 2 (d) 4

The stress-strain curve for an ideally plastic material is

(d) compression in both materials 8.

A column of height ‘H’ and area at top ‘A’ has the same strength throughout its length, under its own weight and applied stress ‘P0’ at the top. Density of column material is ‘  ’. To satisfy the

Civil Engineering

STRENGTH OF MATERIALS

above condition, the area of the column at the bottom should be. (a)

 HP0    Ae g 

(b)

 gH   P0 

10.

(d)

15.

 gH   P  Ae 0   H    gP0 

Ae

A bar of diameter 30 mm is subjected to a tensile load such that the measured extension on a gauge length of 200 mm is 0.09 mm and the change is diameter is 0.0045 mm. The Poisson’s ratio will be (a) 1/4

(b) 1/3

(d) 1/2

16.

The length, coefficient of thermal expansion and Young’s modulus of bar ‘A’ are twice that of bar ‘B’. If the temperature of both bars is increased by the same amount while preventing any expansion, then the ratio of stress developed in bar A to that in bar B will be (a) 2

(b) 4

(d) 16

The lists given below refer to a bar of length L, cross sectional area A, Young’s modulus E, Poisson’s ratio  and subjected to axial stress ‘p’. Match List-I with List-II and select the correct answer using the codes given below the lists: List-I

When a mild-steel specimen fails in a torsiontest, the fracture looks like

List-II 1. 2(1 +  )

A. Volumetric strain

B. Strain energy per unit volume 2. 3(1 – 2  )

(a)

C. Ratio of Young’s modulus to

(b)

p (1  2) E

p2 2E

bulk modulus (c) D. Ratio of Young’s modulus to

(d) 11.

12.

modulus of rigidity

A 2 m long bar of uniform section 50 mm2 extends 2 mm under a limiting axial stress of 200 N/ mm2. What is the modulus of resilience for the bar? (a) 0.10 units

(b) 0.20 units

(d) 200000 units

(b) endurance limit

17.

(d) tolerance limit

105

If E = 2.06 × N/mm 2, an axial pull of 60 kN suddenly applied to a steel rod 50 mm in diameter and 4 m long, causes an instantaneous elongation of the order of (a) 1.19 mm

(b) 2.19 mm

(d) 11.9 mm

IES-1996 14.

Codes:

The stress level, below which a material has a high probability of not failing under reversal of stress, is known as (a) elastic limit

13.

5. 2(1 –  )

A bar of circular cross-section varies uniformly from a cross-section 2D to D. If extension of the bar is calculated treating it as a bar of average diameter, then the percentage error will be (a) 10

(b) 25

(d) 50

18.

(a)

(b)

(c)

(d)

If all dimensions of prismatic bar of square crosssection suspended freely from the ceiling of a roof are doubled then the total elongation produced by its own weight will increase (a) eight times

(b) four times

(d) two times

The stress at which a material fractures under large number of reversals of stress is called. (a) endurance limit

(b) creep

(d) residual stress

Directions: The following items consist of two statements, one labelled the ‘Assertion A’ and the other labelled the ‘Reason R’ you are to examine these two statements carefully and decide if the Assertion A and the Reason R are individually true and if so, whether the Reason is a correct explanation of the IES MASTER Publication

Civil Engineering

STRENGTH OF MATERIALS

ANSWER KEY 1.

(a)

30.

(b)

59.

(c)

88.

(b)

117. (c)

(b)

31.

(a)

60.

(c)

89.

(d)

118. (a)

(c)

32.

(c)

61.

(b)

90.

(d)

119. (b)

(c)

33.

(d)

62.

(d)

91.

(b)

120. (d)

(a)

34.

(c)

63.

(b)

92.

(c)

121. (d)

(c)

35.

(a)

64.

(c)

93.

(c)

122. (b)

(d)

36.

(a)

65.

(d)

94.

(a)

123. (c)

(c)

37.

(d)

66.

(c)

95.

(b)

124. (c)

(b)

38.

(a)

67.

(c)

96.

(b)

125. (b)

10.

(a)

39.

(d)

68.

(b)

97.

(d)

126. (d)

11.

(a)

40.

(b)

69.

(c)

98.

(d)

127. (a)

12.

(b)

41.

(a)

70.

(c)

99.

(c)

128. (c)

13.

(a)

42.

(a)

71.

(a)

100. (a)

129. (a)

14.

(a)

43.

(d)

72.

(c)

101. (d)

130. (b)

15.

(b)

44.

(a)

73.

(c)

102. (a)

131. (b)

16.

(a)

45.

(d)

74.

(a)

103. (a)

132. (a)

17.

(b)

46.

(b)

75.

(a)

104. (d)

133. (*)

18.

(a)

47.

(b)

76.

(d)

105. (d)

134. (b)

19.

(b)

48.

(b)

77.

(c)

106. (c)

136. (c)

20.

(a)

49.

(a)

78.

(a)

107. (c)

136. (c)

21.

(a)

50.

(a)

79.

(b)

108. (c)

137. (b)

22.

(a)

51.

(a)

80.

(b)

109. (a)

138. (a)

23.

(d)

52.

(b)

81.

(c)

110. (a)

139

24.

(c)

53.

(a)

82.

(a)

111. (b)

140. (b)

25.

(c)

54.

(b)

83.

(a)

112. (b)

141. (c)

26.

(d)

55.

(b)

84.

(a)

113. (d)

27.

(a)

56.

(a)

85.

(d)

114. (d)

28.

(d)

57.

(c)

86.

(c)

115. (a)

29.

(a)

58.

(c)

87.

(b)

116. (b)

(a)

IES MASTER Publication