If answering hand written Please answer in clear An inside cylinder locomotive has its cylinder centre lines 1 m apart and has a stroke of 1 m. The rotating masses per cylinder are equivalent to 100 kg at the crankpin, and the reciprocating masses per cylinder to 200 kg. The wheel centre lines are 2 m apart. The cranks are at right angles. The whole of the rotating and 2/3 ofthe reciprocating masses are to be balanced by masses placed at a radius of 0.8 m. Find the magnitude of the balancing mass on the right most wheel.Select one:OA. 55.32 kgB. 322.3 kgC.225.3 kgO D. 115.3 kgFor the data given in Question 1, find the direction (with horizontal) of the balancing mass on the left most wheel.Select one:O A. 115 degreesB.15 degreesO C.215 degreesO D. 45 degrees

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An inside cylinder locomotive has its cylinder centre lines 1 m apart and has a stroke of 1 m. The rotating masses per cylinder are equivalent to 10 pin, and the reciprocating masses per cylinder to 200 kg. The wheel centre lines are 2 m apart. The cranks are at right angles. The whole of the rot the reciprocating masses are to be balanced by masses placed at a radius of 0.8 m. Find the magnitude of the balancing mass on the right most w Select one: OA. 55.32 kg OB. 322.3 kg O C. 225.3 kg O D. 115.3 kg For the data given in Question 1, find the direction (with horizontal) of the balancing mass on the left most wheel. Select one: O A. 115 degrees O B. 15 degrees

An inside cylinder locomotive has its cylinder centre lines 1 m apart and has a stroke of 1 m. The rotating masses per cylinder are equivalent to 10 pin, and the reciprocating masses per cylinder to 200 kg. The wheel centre lines are 2 m apart. The cranks are at right angles. The whole of the rot the reciprocating masses are to be balanced by masses placed at a radius of 0.8 m. Find the magnitude of the balancing mass on the right most w Select one: OA. 55.32 kg OB. 322.3 kg O C. 225.3 kg O D. 115.3 kg For the data given in Question 1, find the direction (with horizontal) of the balancing mass on the left most wheel. Select one: O A. 115 degrees O B. 15 degrees

International Edition---engineering Mechanics: Statics, 4th Edition

4th Edition

ISBN:9781305501607

Author:Andrew Pytel And Jaan Kiusalaas

Publisher:Andrew Pytel And Jaan Kiusalaas

Chapter8: Centroids And Distributed Loads

Section: Chapter Questions

Problem 8.91P: What is the ratio L/R for which the uniform wire figure can be balanced in the position shown?

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