Statics: Reactions at rocker and pin on an A-shaped frame

In summary, the problem involves determining the reactions at rocker support A and pin support B using equilibrium equations. However, before blindly applying these equations, it is important to consider the geometry of the problem to determine the rough directions of the reaction forces. By drawing a line with a gradient of 5 to 8 through point E, the point of intersection of the resultant applied force and the reaction at A can be determined, leading to the conclusion that the reaction at B must also pass through this point. This allows for the creation of a triangle of forces and obtaining an answer within 20% of the algebraically correct answer. It is recommended to consider the problem geometrically before solving it algebraically to avoid errors.
  • #1
JoeS4
7
0

Homework Statement



Determine the reactions at rocker support A and pin support B.

Homework Equations


ƩF = 0
ƩM = 0

The Attempt at a Solution



ƩFx = 0: -Asin(25) - (800lb) + Bx
ƩFy = 0: Acos(25) - (500lb) + By

I'm getting thrown off because of the rocker on an incline.
 

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  • #2
You have made an assumption without declaring it about the direction of the reaction at B, and it contains an inconsistency. Before you apply equilibrium equations blindly, look at the problem geometrically so that you know the rough directions of the answers you seek. In this case, if you draw a line with a gradient 5 to 8 through E in the approximately south west direction, where does this line of the resultant applied force meet the direction of the reaction at A? Why is it that the reaction at B must also pass through this same point? What can you now conclude about the directions of the two reaction forces... and hence their components? Can you now sketch a triangle of forces and obtain an answer to the question within 20% of the algebraically "correct" answer. It is wise to do the rough thought process I have described, before doing the algebra. I concede that very systematic people can solve mechanics problems with no mental picture of it, but it is rare to do so without one or more errors. Looking at the problem geometrically is a form of error trapping.
 

Related to Statics: Reactions at rocker and pin on an A-shaped frame

1. What is meant by "statics" in the context of an A-shaped frame?

Statics is the branch of mechanics that deals with the analysis of forces and their effect on stationary objects. In the context of an A-shaped frame, it refers to the study of the reactions at the rocker and pin, which are the points where the frame connects to the ground.

2. How do you determine the reactions at the rocker and pin on an A-shaped frame?

The reactions at the rocker and pin on an A-shaped frame can be determined by applying the principles of static equilibrium. This involves summing the forces and moments acting on the frame and setting them equal to zero. By doing this, the unknown reactions can be solved for.

3. What factors affect the reactions at the rocker and pin on an A-shaped frame?

The reactions at the rocker and pin on an A-shaped frame are affected by several factors, including the weight and distribution of the load being supported by the frame, the shape and dimensions of the frame, and the angle at which the frame is positioned.

4. How can the reactions at the rocker and pin be adjusted on an A-shaped frame?

The reactions at the rocker and pin on an A-shaped frame can be adjusted by changing the weight or distribution of the load being supported, altering the shape or dimensions of the frame, or adjusting the angle at which the frame is positioned. Additionally, adding supports or braces to the frame can also help redistribute the reactions.

5. Why is it important to understand the reactions at the rocker and pin on an A-shaped frame?

Understanding the reactions at the rocker and pin on an A-shaped frame is important for ensuring the stability and safety of the structure. It allows engineers and designers to properly size and position the frame components to withstand the expected loads and prevent any potential failure or collapse.

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