## Problem 4: Distributed Load Analysis**Given:**Take that \( W_o = 3.8 \, \text{kN/m} \) intensity for the distributed load below. The fixed support at O can have support reactions with a vertical and horizontal force and a moment.### Diagram ExplanationThe diagram shows a beam fixed at one end (point O) with a triangular distributed load applied on it. The triangular load has a peak intensity of \( W_o \), which is given as \( 3.8 \, \text{kN/m} \). The length of the beam is divided into two segments:- The first segment from O to the middle of the beam = 3 m- The second segment from the middle of the beam to the end = 1.5 m### Questions:**A)** Show your free body diagram with the resultant loads, their locations and indicate the support reactions.**B)** What are the support reactions at the fixed support at O?### Answers:**\( M_O = \) __________** **\( O_X = \) __________** **\( O_Y = \) __________**---This problem is designed to help students understand the analysis of beams under distributed loading conditions. It includes practicing drawing free body diagrams, calculating resultant loads, and determining support reactions.

Answered: Image /qna-images/answer/d9364b1c-db0e-411c-ad1d-7814bc868c50.jpg

4) Take that W,= 3.8 kN/m intensity for the distributed load below. The fixed support at O can have support reactions with a vertical and horizontal force and a moment. B) Answers: A) Show your free body diagram with the resultant loads, their locations and indicate the support reactions. Mo= Ox= -3m- Oy= Wo -1.5 m- What are the support reactions at the fixed support at O?

4) Take that W,= 3.8 kN/m intensity for the distributed load below. The fixed support at O can have support reactions with a vertical and horizontal force and a moment. B) Answers: A) Show your free body diagram with the resultant loads, their locations and indicate the support reactions. Mo= Ox= -3m- Oy= Wo -1.5 m- What are the support reactions at the fixed support at O?

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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force, the sign convention is same as that used in lectures and seminars). A simply supported beam is loaded as shown in the Figure. The corresponding SFD and BMD would be: 20 kN 10 kN/m 2 m 2 m 30 kN (a) 40 kN m 30 kN 30 kN 10 kN (b) 40 kN.m 10 kN 30 kN 30 kN Click Save and Submit to save and submit. Click Save All Answers to save all answvers.
> Next question You can retry this question below A triangular distributed load of max intensity w-490 N/m acts on beam AB. The beam is supported by a pin at A and member CD, which is connected by pins at C and D respectively. Determine the reaction forces at A and C. Enter your answers in Cartesian components. Assume the masses of both beam AB and member CD are negligible. cc 030 BY NC SA 2016 Eric Davishahl Variable Value 6.6 m a b C D 11.88 m 4.95 m Values for dimensions on the figure are given in the following table. Note the figure may not be to scale. The reaction at A is A = -11268.69 N. The reaction at Cis C= 11268.69 N. 20 Submit Question Jump to Answer X2-3923.92 B X2+ -8451.52 H X X
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