BIET (CIVIL): April 2014

Saturday, April 5, 2014

HHM - Hydropower Engineering (Notes)

Unit 8: Hydropower Engineering

Thursday, April 3, 2014

HHM - Assignment 2

ANSWER ANY ONE UNIT (ALL QUESTIONS) AND SUBMIT AS ASSIGNMENT

ON OR BEFORE 09-APR-2014

HYDRAULICS AND HYDRAULIC MACHINES

Unit 5: Hydraulic Turbines - I

1. a) How are turbines classified? Explain

b) What is a draft tube? Why is it used in a reaction turbine? Explain with the help of sketches two different types of draft tubes

2. A Pelton wheel is required to develop 12000 kW when working under a head of 300m. It rotates at a speed of 540 rpm. Assuming the jet ratio as 10 and overall efficiency as 84%, calculate the diameter of the wheel, the quantities of water required and the number of jets.

3. A Kaplan turbine works under a head of 22m and runs at 150 rpm. The diameters of the runner and boss are 4.50m and 2.0m respectively. The flow ratio is 0.43. The inlet vane angle at the extreme edge of the runner is 20⁰. If the turbine discharges radially at outlet, determine the discharge and hydraulic efficiency. And also draw the inlet and outlet velocity triangles.

4. An inward flow reaction turbine has inner and outer diameter of the wheel as 350mm and 750mm respectively. The vanes radial at inlet and the discharge is radial of outlet. The water enters the vane at an angle of 15⁰. Assuming the velocity of flow to be constant and equal to 3.5m/sec, Find the speed of the wheel and the vane angle at outlet.

Unit 6: Hydraulic Turbines - II

5. A Francis turbine working under a head of 5 m at a speed of 210 rpm develops 75 KW when the rate of flow of water is 1.8 m³/ sec. If the head is increased to 16 m, determine the speed, discharge and power.

6. A turbine is to operate under a head of 30m and a speed of 300 rpm. The discharge is 10 cumecs. If the efficiency of the turbine is 90%, determine the specific speed of the turbine, Power generated and Type of turbine

7. A hydraulic turbine develops 120 KW under a head of 10 m at a speed of 1200 rpm and gives an efficiency of 92%. Find the water consumption and the specific speed. If a model of scale 1: 30 is constructed to operate under a head of 8m what must be its speed, power and water consumption to run under the conditions similar to prototype.

8. a) What are the physical indicators for the presence of cavitations in turbines?

b) What do you understand by unit speed of a turbine? What is its use?

Unit 7: Centrifugal Pumps

9. Centrifugal pump discharges 1200 lit/minute against a head of 16.5 m when the speed is 1500 rpm. The diameter of the impeller is 35 cm and the power required is 6 H.P. A geometrically similar pump of 45 cm is to run at 1750 rpm. Assuming equal efficiency, Find i) the head developed ii) the discharge and iii) power developed by the 45 cm pump.

10. How are pumps classified? Quote the approximate values of specific speed for different types.

11. The impeller of a centrifugal pump has 1.2 m outside diameter. It is used to lift 1.8 m³/s of water to a height of 6m. Its blades make an angle of 150⁰ with the direction of motion at outlet and runs at 200 rpm. If the radial velocity of flow at outlet is 2.5m/s, find the useful H.P and efficiency

12. A centrifugal pump 20 cm diameter running at 1450 rpm delivers 0.1 m³/s against a head of 40 m with an efficiency of 90%. Determine its specific speed.

Unit 8: Hydropower Engineering

13. Draw the typical layout of hydroelectric power plant and explain its components.

14. Where is the location of surge tank in hydro power installation? Explain with a neat sketch.

15. Write down the advantages and disadvantages of hydroelectric power plants.

16. Explain different measures to be taken for safe operation of hydroelectric power plants

DSS - Assignment 2

ANSWER ANY ONE UNIT (ALL QUESTIONS) AND SUBMIT AS ASSIGNMENT

ON OR BEFORE 09-APR-2014

Design of Steel Structures (DSS)

Unit 5: Beams

1. Design a beam of effective span 6 m subjected to UDL of 10 kN/m and two concentrated loads of 80 kN each at 2m and 4m respectively from the left support. The beam is laterally supported.

2. A hall 12m x 8 m has to be provided with a 120mm thick roof slab. The roof shall also be provided with 75 mm thick cement concrete. The live load on the slab is 1.5 kN/m². Design an intermediate steel beam, if the beams are spaced at 3 m c/c

3. Find the superimposed live load carrying capacity of ISMB 400@0.822 KN/m, if it to be used over a simply supported effective span of 6.4 m. The beam is laterally supported.

4. Design a laterally unsupported beam with 6 m simply supported effective span, subjected to UDL of 20 kN/m over entire span and a point load of 40 kN at mid span. Depth of beam is restricted to 350 mm

Unit 6: Eccentric Connections

5. An ISLB 225 @ 230.5 N/m and 1 m long is connected at one end to the column section ISHB 200 @ 365.9 N/m. It supports a load of 300 kN at its free end. Design the Bolted connection.

6. Design a framed connection to connect an ISLB 350 @ 485.6 N/m transmitting an end reaction of 300 kN to the web of ISMB 550 @ 1017.3 N/m. Design the Bolted connection.

7. A load of 150 kN is to be transferred through a bracket plate of 12mm thick to the flange of a column section ISHB 300 @ 618 N/m. The load is acting at an eccentricity of 100mm from the column face. Design Bolted connection

8. Draw the typical sketches to show the following beam column connections:

a). Framed Connection b). Unstiffened Seated Connection c) Stiffened Seated Connection

Unit 7: Plate Girders

9. Design a welded plate girder 24 m in effective span and simply supported at ends. It carries an uniformly distributed load of 100 kN/m. draw section at support and front elevation of plate girder

10. What are stiffeners and why are they used? How many types of stiffeners are being used in the design of plate girder? Give the conditions (as per IS 800) when stiffeners are required.

11. A plate girder is subjected to a maximum factored moment of 4000 kN-m and factored shear force of 600 kN. Design girder without any stiffeners

12. A plate girder with Fe415 plates is having 12mmx150mm web plate and 56mm x 500mm flange plates. Determine the flexural strength, if the compression flange supported laterally.

Unit 8: Roof Truss

13. Explain various types of Roof Trusses with neat sketch

14. Draw a Flink Roof Truss of 12m span. Explain and label following members on

a) Top Chord Members

b) Bottom Chord Members

c) Struts

d) Slings

e) Sag Tie

15. Find member forces in a steel roof truss as shown in Fig. for a clear span of 12.45 m. The trusses supported over masonry columns 45cm x 45 cm. The trusses are placed at 3 m c/c and support galvanized iron sheet on rafters and steel purlins. The rise of the truss is 1/3 of span and tile wind normal to the roof surface is 1500 N/m²

16. Design a channel section purlin for the following data:

Spacing of Trusses: 4m

Spacing of Purlins: 1.8m

Weight of Sheets: 100 N/m²

Weight of Purlin: 100 N/m

Live Load: 0.5 kN/m²

Wind Load: 1.5 kN/m² (Suction)

Inclination of main Rafter is 20⁰

Wednesday, April 2, 2014

Major Project - IV Year (Internal Viva)

Bharat Institute of Engineering & Technology (BIET)
Department of Civil Engineering

Major Project - IV Year

(Internal Viva)

All students in a team should meet concerned project guide along with Project Report (Spiral Bind)
All students should take Project Viva by the Guide for 50 Marks and should get Signature
All students should take Signature from HOD
FINAL PROJECT REPORT should be printed only after taking signatures from both Guide and HOD
Marks which are given by the concern guide will be finalized by HOD based on your performance and explanation.
Last date: 03-Apr-2014

Comprehensive Viva - IV Year

Bharat Institute of Engineering & Technology (BIET) Department of Civil Engineering
Comprehensive Viva - IV Year Date: 03-Apr-2014 Time: 10.00am to 12.30pm and 1.30pm to 4pm No. of Interviews: 2 Note: Negative marks will be given to students who doesn't follow the below: Formals (10 Marks) ID Cards (5 Marks) Lack of discipline during interview (5 Marks)
S.No.	Roll Number	Student Name	Panel 1 (50 Marks)	Panel 2 (50 Marks)
1	08E11A0108	CHAITANYA D
2	08E11A0116	JOYCE RAJ
3	08E11A0119	MERCY RAJ
4	09E11A0124	PARIKSHITH T
5	09E11A0128	RAJA SEKHARA REDDY N
6	10E11A0101	ABHISHEK P
7	10E11A0102	ASWANI B
8	10E11A0103	BHARATH CHANDER T
9	10E11A0105	DEEPTHI L
10	10E11A0106	DIVYASRI N
11	10E11A0107	EJAZ AHMED
12	10E11A0108	HARISH B
13	10E11A0109	JAYAKRISHNA S
14	10E11A0110	JYOTHI D
15	10E11A0111	KARTHIK KUMAR G
16	10E11A0113	MADHUSUDHAN K
17	10E11A0114	MADHUSUDHAN REDDY P
18	10E11A0115	MAHENDER L
19	10E11A0116	MAHESH CH
20	10E11A0117	MAHESH KUMAR R
21	10E11A0118	MALAVIKA N
22	10E11A0119	MOHAN N
23	10E11A0120	NANDA KAMAL B
24	10E11A0121	NANDA KISHORE K
25	10E11A0122	NARESH N
26	10E11A0123	NAVEEN KUMAR T
27	10E11A0124	NEHA SHIREEN
28	10E11A0125	PRADEEP KUMAR K
29	10E11A0126	RAGHAVENDER REDDY M
30	10E11A0128	RAMSAGAR M
31	10E11A0129	RAVI K
32	10E11A0130	RAVI TEJA G
33	10E11A0131	ROHIT SAI SANJEEV Y
34	10E11A0132	SAHITH REDDY M
35	10E11A0133	SAI SANDEEP REDDY B
36	10E11A0134	SHARATH CHANDER T
37	10E11A0135	SHIRISHA REDDY G
38	10E11A0136	SINDHU D
39	10E11A0137	SPANDANA G
40	10E11A0138	SRAVAN REDDY M
41	10E11A0140	SRIKANTH J
42	10E11A0141	SUKESH K
43	10E11A0142	SUPRIYA B
44	10E11A0143	SUPRIYA K
45	10E11A0144	SUSHMITHA E
46	10E11A0145	SWATHI B
47	10E11A0147	VAKEEL MA
48	10E11A0148	VENKAT REDDY B
49	10E11A0149	VENKAT REDDY J
50	10E11A0150	VIJAY B
51	10E11A0151	VIKAS G
52	10E11A0152	VIKAS K
53	10E11A0153	VINAY KUMAR G
54	10E11A0154	VINEETH REDDY J
55	10E11A0155	SURAJ SAHANI
56	10E11A0156	JHANSI LAXMI T
57	10E11A0158	YASHWANTH V
58	10E11A0159	MANOJ REDDY M
59	10E11A0160	SRAVANI R
60	11E15A0101	SRILATHA S
61	11E15A0102	VINOD KUMAR V
62	11E15A0103	SANTOSH CH
63	11E15A0104	PRAVEEN KUMAR A
64	11E15A0105	NARASAMMA D
65	11E15A0106	AMRUTHA S
66	11E15A0107	SAI KUMAR B

BIET (CIVIL)