QUESTIONBANKEE1302-TRANSMISSION&DISTRIBUTION ENGINEERING

2. QUESTIONBANKEE1302-TRANSMISSION&DISTRIBUTION ENGINEERING

3.  SUBJECT CODE/NAME: EE1302-TRANSMISSION & DISTRIBUTION ENGINEERING

4.  

5. YEAR / SEM : III / V

6.  

7. UNIT- I

8.  

9. TRANSMISSION SYSTEM

10.  

11. What is meant by power supply system?

12. What is meant by Transmission and Distribution system?

13. What are the different types of Power supply system?

14. What are the various components of power supply system?

15. What are the different types of power plants?

16. What are the different operating voltages used for generation, primary and

17. secondary transmission in AC power supply systems in India?

18. Define – Feeder, distributor and service mains.

19. List the advantages of high voltage transmission.

20. State Kelvin’s law.

21. What are the limitations of Kelvin’s law?

22. Define – Break-even distance.

23. List the disadvantages of DC transmission.

24. List the different types of DC links.

25. Define – Short Circuit Ratio (SCR)

26. What are the limitations of high voltage transmission?

27. List the various types of distribution systems.

28. 17.List the different types of distribution systems based on connection

29. 18. What are the different components of a distribution system?

30. What are the limitations of HVDC system?

31. List the two merits of HVDC system

32. List the HVDC systems present and which are in operation in India.

34.  

36. List the applications of HVDC system.

37. List the advantages of EHVAC transmission system.

38. What is the need of load dispatch centres? Where are the LDC's available in Tamil Nadu?

39.  

40.  

41. 	PART-B
    1.(i)Discuss various types of HVDC links.		(8)
    	(ii)List out the main components of a HVDC system.	(8)
    2.(i) Draw and explain the structure of modern power systems with typical		(13)
    	voltage levels.
    	(ii)What is the highest voltage level available in India?	(3)
    3.	(i).Explain the effect of high voltage on volume of copper and on efficiency. (8)
    	(ii) Explain why the transmission lines are 3 phase 3-wire circuits while	(8)
    	distribution lines are 3 phase 4-wire circuits.
    4.	(i) Draw the model power system with single line representation. Show its	(6)
    	essential constituent sections.
    	(ii) What are the AC transmission and distribution level voltages we have in
    	India?	(4)
    	(iii) What are the different kinds of DC links? Draw relevant diagrams.	(6)
    5.	(i)Explain why EHV transmission is preferred? What are the problems involved
    	in EHV AC transmission?	(8)
    	(ii) With neat schematic, explain the principle of HVDC system operation.	(8)
    6.	Explain about FACTS with neat diagram	(16)
    7.	Explain TCSC and SVS systems	(16)
    8.	Explain with neat diagram about STATCOM and UPFC	(16)
    9.	(i) Compare EHVAC and HVDC transmission	(8)
    	(ii) Explain the applications of HVDC transmission system	(8)

42.  

43.  

44. UNIT- II

45.  

46. TRANSMISSION LINE PARAMETERS

47.  

48. PART-A

49.  

50. Define Skin effect.

51. What is meant by proximity effect?

52. List out the advantages of double circuit lines.

53. Define - Self and mutual – G.M.D.

54. Self GMD (GMR):

55. What is meant by inductive interference?

56. What is transposition of conductors?

57. State why transposition of line conductors are needed?

59.  

61.  

62. List the advantages of bundled conductors.

63. What are the factors that affect the skin effect?

64. Why the effective resistance is more than the static resistance of a transmission line?

65. Why does a transmission lines have resistance, inductance, and capacitance?

66. List the factors that governing the capacitance of a transmission line.

67. What is ACSR conductor?

68. What is fictitious conductor radius?

69. State the advantages of double circuit line over single circuit line.

70. Define unsymmetrical spacing.

71. Define symmetrical spacing.

72. Define capacitor.

73. What do you understand by inductive interference?

74.  

75. PART-B

76.  

77. 1.  From the fundamentals derive an expression for inductance of a single phase

78. transmission system.	(16)
    2. Derive an expression for capacitances of a single phase transmission system
    and discuss the effect of earth on capacitance with suitable equation.	(16)
    3. (i) Derive an expression for inductance of a single-phase overhead line.	(8)
    (ii) A conductor is composed of seven identical copper strands each having a
    radius r. Find the self-GMD of the conductor.	(8)
    4. i)     Derive an expression for the capacitance between conductors of a single
    phase overhead line.	(8)
    ii)    Find the capacitance between the conductors of a single-phase 10 km long line.
    The diameter of each conductor is 1.213cm. The spacing between conductors is
    1.25m. Also find the capacitance of each conductor neutral.	(8)
    5. i) Derive the expression for inductance of a two wire 1Φ transmission line	(8)
    ii) Derive the expression for capacitance of a 1Φ transmission line	(8)
    6. i)What are the advantages of bundled conductors?	(4)

79. ii)  Derive  the  expression  for  capacitance  of  a  double  circuit  line  for  hexagonal

80. spacing.	(8)
    iii) Why is the concept of self GMD is not applicable for capacitance?	(4)

81. 7. i) Explain clearly the skin effect and the proximity effects when referred to overhead lines. (8)

82. ii) Write a short note on the inductive interference between power and communication lines. (8)

83. i) Derive the expression for the capacitance per phase of the 3 Φ double circuit line flat vertical spacing

84. with transposition. (8)

85. ii) A 3 Φ overhead transmission line has its conductors arranged at the corners of an equilateral

86. triangle of 2m side. Calculate the capacitance of each line conductor per km. Given the diameter of

87. each conductor is 1.25cm. (8)

88. 9. Find the capacitance per km per phase of a 3Φ line arrangement in a horizontal

90.  

92. plane spaced 8 metres apart. The height of all conductors above the earth is 13

93.  

94. metres. The diameter of each conductor is 2.6 cm. the line is completely transposed and takes the

95. effect of ground into account. (16)

96. 10. Discuss the concept of GMR and GMD in the calculation of transmission line inductance. (16)

97.  

98. UNIT- III

99.  

100. MODELLING AND PERFORMANCE OF TRANSMISSION LINES

101.  

102. PART- A (2 MARKS)

103.  

104. Classify overhead transmission lines.

105. Define transmission efficiency.

106. What is a transmission line?

107. List out the common methods of representation of medium transmission lines.

108. Define regulation of power transmission line.

109. What is tuned power line?

110. What is surge impedance loading or natural loading?

111. What are the voltages regulating equipments used in transmission systems?

112. What is attenuation in a power transmission line?

113. What are the units of generalized constants of a transmission line?

114. What is the range of surge impedance for an overhead transmission line?

115. What is a power circle diagram?

116. What is meant by the receiving end power circle diagram?

117. What is Ferranti effect?

118. What is the cause of Ferranti effect?

119. Define corona.

120. What is local corona?

121. Define critical disruptive voltage.

122. What are the methods adopted to reduce corona?

123.  

124. Is there any advantage on corona?

125. What is the use of power circle diagram?

126. What are the causes of voltage drop and line loss in a transmission line?

127. What are the advantages of using series compensation?

128. What are the main disadvantages of corona?

129. Define sag.

130. What is stringing chart?

131. What are the uses of stringing chart?

132. What are the factors which govern the performance of a transmission line?

133. What is the reason for sag in transmission line?

134.  

135. PART-B

137.  

138. 	1. Determine the efficiency and regulation of a 3phase, 100Km, 50 Hz		transmission
     	line delivering 20 MW at a power factor of 0.8 lagging and 66 kV to a balanced load.
     	The conductors are of copper, each having resistance
     	0.1 Ω / Km, 1.5 cm outside dia, spaced equilaterally 2 metres between centres. Use
     	nominal T method.		(16)

139. 2. A three phase 5 km long transmission line, having resistance of 0.5 Ω / km and inductance of

140. 1.76mH/km is delivering power at 0.8 pf lagging. The receiving end voltage is 32kV. If the supply

141. end voltage is 33 kV, 50 Hz, find line current, regulation

142.  

143. and efficiency of the transmission line.	(16)
     3. Derive the expressions for sending end voltage in nominal T method and end	(16)
     Condenser method.

144. i) What is an equivalent p circuit of long line? Derive expression for

145. parameters of this circuit in terms of line parameters.                                                                            (8

146. )ii) A 50Hz transmission line 300 km long total series impedance of 40+j25 Ω and total shunt admittance

147. of 10   mho. The 220 Kv with 0.8 lagging power factor. Find the

148. sending end voltage, current, power and power factor using nominal p method.(8)

149.  

150. 5. i) Define regulation of a transmission line and derive the approximate expression for

151. the regulation of a short transmission line.	(8)
     ii) What is corona loss? How do you determine this loss?	(8)

152. 6. A 220kV, 3Φ transmission line has an impedance per phase of (40+j200)Ω and an admittance of

153. (0+j0.0015) mho. Determine the sending end voltage and sending end current when the receiving end

154. current is 200 A at 0.95 pf lagging. Use nominal T method. (16)

155.  

156. Determine the efficiency and regulation of a three phase 200 km, 50Hz transmission line delivering

157. 100MW at a pf of 0.8 lagging and 33kV to a balanced load. The conductors are of copper, each

158. having resistance 0.1 Ω/km, and 1.5cm outside dia, spaced equilaterally 2m between centres. Neglect

159. leakage reactance and use nominal

160. T and π methods.		(16)
     8. i) Explain the Ferranti effect with	aphasor diagram and its causes.	(6)
     ii) Explain the classification of lines based on their length of transmission.		(4)
     iii) What are ABCD constants.		(6)
     	UNIT- IV

161.  

162. INSULATORS AND CABLES

163.  

164. PART- A ( 2 MARKS)

165.  

166. What is the purpose of insulator?

167. What are the important characteristics that an overhead line insulator must provide?

168. What are the materials used for overhead line insulators?

169. List out various types of insulators used for overhead transmission lines.

170. Mention the advantages of the pin type insulator.

171. What are the main causes for failure of insulators?

172. What are the different tests that are conducted on an insulator?

174.  

176. Write short notes on puncture test.

177. Define impulse ratio.

178. What are the routine tests conducted on insulators?

179. What are the performance tests conducted on insulators?

180. What are the merits of under ground cables?

181. What is meant by efficiency of an insulator string?

182. What is the main purpose of bedding?

183. What are the common materials used for insulation?

184. What is the main purpose of armouring?

185. What is serving?

186. What is dielectric stress?

187. What is grading of cables?

188. What are the main advantages of suspension type insulators over pin type ones?

189. What are the methods for improving string efficiency?

190. Name the two methods of locating cable faults.

191. State two types of faults in a cable.

192.  

193. PART-B

194.  

195. 1.Discuss any two methods to increase the value of string efficiency, with suitable

196. sketches.	(16)
     2.Explain any two methods of grading of cables with necessary diagrams.	(16)

197. i) What are different methods to improve string efficiency of an insulator?    (8)

198. In a 3-unit insulator, the joint to tower capacitance is 20% of the capacitance of each

199. unit. By how much should the capacitance of the lowest unit be increased to get a

200. string efficiency of 90%. The remaining two units are left unchanged.	(8)
     4. i)Derive the expression for insulator resistance, capacitance and electric stress
     in a single core cable. Where is the stress maximum and minimum?	(8)

201. ii) A single core 66kv cable working on 3- phase system has a conductor diameter of 2cm

202. and sheath of inside diameter 5.3cm. If two inner sheaths are introduced in such a way that

203. the stress varies between the same maximum and minimum in the three layers find:

204.  

205. a)  position of inner sheaths
     b)  voltage on the linear sheaths		(8)
     c)  maximum and minimum stress
     5.i)Draw the schematic diagram of a pin type insulator and explain its function(8)
     ii) A 3 phase overhead transmission line is being supported by three disc
     insulators. The potential across top unit (i.e. near the tower) and the middle
     unit are 8kV and 11kV respectively. Calculate,
     a)	The  ratio  of  capacitance  between  pin  and  earth  to  the  self  capacitance  of
     	each unit	(4)
     b)	Line Voltage	(2)
     c)	String Efficiency	(2)

207.  

209.  

210. 6.i) Describe with the neat sketch, the construction of a 3 core belted type cable. (8)

211.  

212. ii) A conductor of 1cm diameter passes centrally through porcelain cylinder of internal diameter

213. 2 cms and external diameter 7cms. The cylinder is surrounded by a tightly fitting metal sheath.

214. The permittivity of porcelain is 5 and the peak voltage gradient in air must not exceed 34kV/cm.

215. Determine the maximum safe working voltage. (8)

216. 7.i) What are the various properties of insulators? Also briefly explain about suspension type insulators. (8)

217. ii) Calculate the most economical diameter of a single core cable to be used on 132kV, 3 phase system.

218. Find also the overall diameter of the insulation, if the peak

219. permissible stress does not exceed 60kV/cm. Also derive the formula used.	(8)
     8. i) Briefly explain about various types of cables used in underground system.	(8)

220. A string of 4 insulator units has a self capacitance equal to 4 times the pin to earth capacitance.

221. Calculate,

222. Voltage distribution as a % of total voltage

223. b)  String efficiency	(8)
     9. i) Give any six properties of a good insulator.	(4)
     ii) With a neat diagram, explain the strain and stay insulators.	(4)

224. A cable is graded with three dielectrics of permittivities 4,3 and 2. The maximum permissible

225. potential gradient for all dielectrics is same and equal to 30 kV/cm.

226. The core diameter is 1.5cm and sheath diameter is 5.5cm.	(8)
     10.i) Explain the constructional features of one LT and HT cable	(8)
     ii) Compare and contrast overhead lines and underground cables.	(8)

227.  

228.  

229. UNIT- V

230.  

231. SUBSTATION GROUNDING SYSTEM AND DISTRIBUTION SYSTEM

232.  

233. PART- A (2 MARKS)

234.  

235.  

236. What are the conditions of laying out a substation?

237. What are the classifications of substation according to service?

238. What are the types of transformer substations?

239. What are the classifications of substations due to construction? 6.What are the equipments used in a transformer substation?

240.  

241. 7.What are the different types of bus bar arrangements in substations?

242.  

243. What are the materials mainly used in busbars?

244. What are the factors to be considered for busbar design?

245. Which tests are necessary on station busbars?

246. What is neutral grounding or neutral earthing?

247. What is equipment grounding?

248. What are the advantages of neutral grounding?

250.  

252. What is earth resistance?

253. What are the devices used for DC power at the substation by using converting machinery?

254. Define distribution substation.

255. Define service mains?

256. What are the types of nature of current in distribution system?

257.  

258. 	PART-B
     1.	With a neat sketch explain double bus with double breaker and double bus with
     single breaker. State their advantages and disadvantages.		(16)
     2.Explain the following:
     	(i) Neutral grounding	(16)
     	(ii) Resistance grounding.
     3.	Explain about the various types of substations	(16)
     4.	Write short notes on	(4)
     	I.   Sub mains
     	II.   Stepped and tapered mains	(12)
     5.	Explain the substation bus schemes.	(16)
     6.	Write short notes on	(8)
     	i. Busbar arrangement in substation
     	ii. Grounding grids	(8)
     7. i) Explain the design principles of substation grounding system.		(8)
     	ii) Explain the equipments in a transformer substation.	(8)

260.  

261.  

263.