Difference between revisions of "Chapter 4 Problem 67"

Problem

A block (mass ${\displaystyle m_{A}}$) lying on a fixed frictionless inclined plane is connected to a mass ${\displaystyle m_{B}}$ by a cord passing over a pulley.

(a) Determine a formula for the acceleration of the system in terms of ${\displaystyle m_{A}}$, ${\displaystyle m_{B}}$, ${\displaystyle \theta }$, and ${\displaystyle g}$.

(b) What conditions apply to masses ${\displaystyle m_{A}}$ and ${\displaystyle m_{B}}$ for the acceleration to be in one direction (say, ${\displaystyle m_{A}}$ down the plane), or in the opposite direction? Ignore the mass of the cord and pulley.

Solution

Notice there are two coordinate systems A and B! However, the connection between them is trivial due to cord, and you save time in the end.

(a)

notice that in the chosen coordinate systems, ${\displaystyle a_{yA}=0}$ and ${\displaystyle a_{xB}=0}$

${\displaystyle \sum F_{yA}=F_{N}-m_{A}g\cos \theta =0}$ ${\displaystyle \rightarrow F_{N}=m_{A}g\cos \theta }$

${\displaystyle \sum F_{xA}=m_{A}g\sin \theta -F_{T}=m_{A}a_{xA}}$

${\displaystyle \sum F_{yB}=F_{T}-m_{B}g=m_{B}a_{yB}\rightarrow F_{T}=m_{B}\left(g+a_{yB}\right)}$

The connection between the blocks mean ${\displaystyle a_{yB}=a_{xA}=a}$

${\displaystyle m_{A}g\sin \theta -m_{B}(g+a)=m_{A}a\rightarrow m_{A}g\sin \theta -m_{B}g=m_{A}a+m_{B}a}$

${\displaystyle a=g{\frac {\left(m_{A}\sin \theta -m_{B}\right)}{\left(m_{A}+m_{B}\right)}}}$

(b)

If the acceleration is down the plane, ${\displaystyle a>0}$ :

${\displaystyle m_{A}\sin \theta <m_{B}}$

if the acceleration is up the plane ${\displaystyle a<0}$

${\displaystyle m_{A}\sin \theta >m_{B}}$