https://euler.vaniercollege.qc.ca/gwikis/pwiki/index.php?action=history&feed=atom&title=Newtons_Laws_EX_3Newtons Laws EX 3 - Revision history2026-04-20T21:10:55ZRevision history for this page on the wikiMediaWiki 1.43.0https://euler.vaniercollege.qc.ca/gwikis/pwiki/index.php?title=Newtons_Laws_EX_3&diff=294&oldid=previmported>Patrick at 18:30, 26 May 20112011-05-26T18:30:34Z<p></p>
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There is a 100 N gravitational force acting on each block in the above diagram. <br><br />
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Considering the four blocks on the floor we will select a horizontal x-axis and a vertical y-axis pointing up. <br><br />
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We will assume that the blocks will not move up or down. It means that the sum of the vertical components of all forces acting on each block is zero.<br />
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We note that we need to consider only y-components of the three forces acting on each block <math>F_G</math> ,<math>F_N</math> and <math>F</math> because <math>F_N</math> has components (0, <math>F_N</math>).<br><br><br />
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1. The sum of the y-components of forces acting on the first block is <br><br />
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<math>- 100 + 50 + F_N = 0</math> and therefore <math>F_N = 50 N</math>. <br><br><br />
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2. The sum of the y-components of forces acting on the second block is <br><br />
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<math>- 100 - 50 + F_N = 0</math> and therefore <math>F_N = 150</math> N. <br><br><br />
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3. The sum of the y-components of forces acting on the third block is <br><br />
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<math>- 100 + 50 sin 60^o + F_N = 0</math> and therefore <math>F_N = 57</math> N. <br><br><br />
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4. The sum of the y-components of forces acting on the fourth block is <br><br />
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<math>- 100 + 50 sin (- 60^o) + F_N = 0</math> and therefore <math>F_N = 143</math> N. <br><br><br />
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Similarly, the block pushed towards the ceiling has only three forces acting on it. <br><br />
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Focusing only on the y-components of forces we write: <br><br />
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<math>- 100 + 110 + F_N = 0</math> <br><br />
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and therefore:<br><br />
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<math>F_N = - 10</math> N. <br><br />
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It means that the ceiling exerts a downward normal force on the block. <br><br />
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Considering the block that is pushed with a horizontal force pointing towards the wall we will focus on the x-components of forces acting on the block. There are only two such horizontal forces. <br><br><br />
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''We will assume that the block does not move in a horizontal direction''.<br><br><br />
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Therefore the two horizontal forces balance each other and consequently, <math>F_N = 50</math> N points to right. <br><br><br />
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''We assume that the block on the incline does not move in a direction perpendicular to the incline''. <br><br><br />
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By selecting x-axis parallel to the incline plane and y-axis pointing up from the incline plane, we need to focus on y-components of the gravitational force and the normal force which balance each other since the block does not move in this direction. <br><br><br />
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Since the gravitational force makes an angle - <math>120^o</math> with x-axis we can compute the y-component of the gravitational force to be:<br><br />
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<math>F_G sin (- 120^o) = 100 x 0.867 = 86.7</math> N. <br><br />
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The y-component of the normal force is <math>F_N</math> and it balances the y-component of the gravitational force. <br />
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Therefore, the normal force is:<br><br />
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<math>F_N = 86.7</math> N.<br></div>imported>Patrick