1. Calculate the horizontal (x) component of the reaction (supporting) force (lb) at point A.2. Calculate the vertical (y) component of the reaction (supporting) force (lb) at point A.3. Calculate the magnitude of the total reaction force (Ib) at point A.4. Calculate the horizontal (x) component of the reaction (supporting) force (b) at point D.5.Calculate the vertical (y) component of the reaction (supporting) force (Ib) at point D. Consider the situation below in which a steel beam is supported by a column at one end (at A)and is supported (at B) part way along its length by a wall. The beam is pinned to the columnat A and is supported by a roller connection at B.The beam has applied loads as shown in the figure (dark gray vectors).columnA8pinned6'1100 lb500 lbIX. I60%700 lbBbeam12'rollerwall6'Based on this information, complete the questions / calculations below.NOTE: Depending on the specific way in which you choose to solve this problem, the order in whichyou solve for each of the required variables may NOT be the order listed below. In general, you

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Mechanical Engineering

1. Calculate the horizontal (x) component of the reaction (supporting) force (lb) at point A. 2. Calculate the vertical (y) component of the reaction (supporting) force (lb) at point A. 3. Calculate the magnitude of the total reaction force (Ib) at point A.

Mechanics of Materials (MindTap Course List)

9th Edition

ISBN:9781337093347

Author:Barry J. Goodno, James M. Gere

Publisher:Barry J. Goodno, James M. Gere

Chapter2: Axially Loaded Members

Section: Chapter Questions

Problem 2.5.23P: Wires B and C are attached to a support at the left-hand end and to a pin-supported rigid bar at the...

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