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Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Civil Engineering (CE) MCQ


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10 Questions MCQ Test - Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion for Civil Engineering (CE) 2024 is part of Civil Engineering (CE) preparation. The Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion questions and answers have been prepared according to the Civil Engineering (CE) exam syllabus.The Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion MCQs are made for Civil Engineering (CE) 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises, MCQs and online tests for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion below.
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Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 1

Which is the cheapest device for measuring flow / discharge rate.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 1

Explanation: Orificemeter is the cheapest available device for measuring flow/discharge rate.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 2

The principle of Orificemeter is same as that of Venturimeter.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 2

Explanation: The working principle for both Orificemeter and Venturimeter is same.

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Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 3

 What is the relationship between Orificemeter diameter and pipe diameter

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 3

Orifice meter diameter is one-fourth times the pipe diameter

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 4

The Orificemeter readings are more accurate than Venturimeter.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 4

Explanation: The Venturimeter readings are more accurate than Orificemeter.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 5

 The Orificemeter readings are more accurate than Pitot tube readings.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 5

Explanation: The Pitot tube readings are more accurate than Orificemeter.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 6

The Orificemeter has a smooth edge hole.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 6

Explanation: The Orificemeter has a rough edge hole.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 7

A nanometre is connected to a section which is at a distance of about 4 to 6 times the pipe diameter upstream from orifice plate.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 7

Explanation: A manometre is connected to a section which is at a distance of about 1.5 to 2.0 times the pipe diameter upstream from orifice plate.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 8

 Venturimeter is based on integral form of Euler’s equation.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 8

Explanation: Venturimeter is based on Bernoulli’s equation.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 9

 Orifice Meter can only be used for measuring rate of flow in open pipe like structure.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 9

Orifice Meter can only be used for measuring rate of flow in an enclosed pipe like structure. 
Depending on your system, use a bucket and a stopwatch to measure flow. Attach a tube or hose onto your spigot and time how long it takes to fill a 5 gallon bucket. If your spigot can fill a 5 gallon bucket in 47 seconds, you can figure out the flow rate with the following formula. Flow rate = volume / time.

Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 10

Orifice meter consists of a flat rectangular plate.

Detailed Solution for Test: Introduction, Euler’s & Bernoulli’s Equation Of Motion - Question 10

Explanation: Orifice meter consists of a flat circular plate.

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