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in this video lecture i am going to
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explain
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how to use macaulay's method to
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determine the deflection in a
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simply supported beam with an example
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problem before moving on to solving
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the problem let me give an overview
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about
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what is macaulay's method and how it
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works it's a simple
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method which works based on the double
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integration concept
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in which the bending moment is given by
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the equation
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e i d square y by d x square in this
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method bending moment at any section x
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is determined in a systematic order
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the section x should be taken either in
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the first
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or the last portion of the beam the
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slope
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dy by dx is obtained by
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integrating the bending moment equation
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that means the integrating the bending
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moment equation
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we can get the slope value
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again by integrating this slope equation
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we can get the deflection of b so
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again if you integrate this equation
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we are going to get the deflection value
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that is why we say that it works based
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on the double integration concept
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now let us solve the problem so if we
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read the problem
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a beam of length 6 meter is simply
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supported at its ends
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and carries two point loads of 48 kilo
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newton
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and 45 kilo newton at a distance of
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one meter and three meter respectively
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from
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left support determine the deflection
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under each load consider the young's
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modulus as
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2 multiplied by 10 to the power 5 newton
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per mm square
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and the moment of inertia value was
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85 multiplied by 10 to the power 6
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millimeter power
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4 first let us construct the given
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system we have 2 point load 48 kilo
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newton and 40 kilo newton
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which are located at a distance of 1
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meter and
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3 meter from the left support the entire
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length of the beam is
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6 meter it is simply supported
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to construct a free body diagram we must
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know the value of reaction force at a
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and reaction
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force at b at a we have a reaction force
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which is r
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a and at b we have a reaction force
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rb now let us find out the reaction
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forces at
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a and b for that we need to apply the
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equilibrium concept
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that is sigma fy is equal to 0
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that means the net forces which are
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acting in the vertical direction
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is equal to zero so r
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a plus rb that means the net forces
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which are acting in the upward direction
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is equal to 48 plus 40 and these two are
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the point loads which are acting in the
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downwards direction r a plus rb
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is equal to 88
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and then we will apply the next
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equilibrium condition
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that is moment about any point is equal
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to zero here we take moment about
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a is equal to 0 so the first
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force which creates the moment about a
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is rb
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rb multiplied by the distance between
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a b which is 6 meter it creates a
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counter clockwise moment it creates a
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counter clockwise moment about a
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so we put positive sign here the next
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moment is created by this point load 40
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kilo newton
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above point a it creates
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clockwise moment about a so we put
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minus sign here 40 multiplied by
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the distance between a and d which is 3
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so 40 multiplied by 3
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the next moment is created by this point
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load 48 kilo newton
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above 0.8 which is 48 multiplied by
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1 meter is equal to 0
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by solving this equation we can find
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the value of rb which is equal to 28
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kilo newton after substituting this
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rb value in this equation we can get the
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value of
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r a which is equal to 60 kilo newton
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now we have calculated the reaction
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forces at a
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and b now the free body diagram is
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complete now let us see how to apply the
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mccollux method to find out the
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deflection
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in the simply supported beam
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so this is the free body diagram and
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here
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the position of c and d are referred
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from the
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right support b so this distance ac is
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1 meter the entire beam length is 6
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meter so
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this length that is c to b measures 5
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meter
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similarly a to d it is given as 3 meter
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so the remaining length is 3 meter that
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is d 2 b
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now we are going to consider a section
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x in the first part of the beam that is
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the section ac which is located at a
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distance of
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x from the right support p
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it is the first step in mccallis method
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now
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we have to find out the distance of
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force
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at c and d with respect to this section
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x
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so this distance is going to be x minus
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3 meter because the total distance is x
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and this distance is 3 meter so it is
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going to be x minus
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3 meter and this distance is
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x minus 5 meter now let us calculate the
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moment
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about this section x so according to
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mccollum's method we represent the
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pending moment as e i d square y by d x
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square
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which is equal to the moment about
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gex so the moment about x is
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found by using the moments which are
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created by the reaction force
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and these two point loads first
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this moment is created by this force
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multiplied by this distance
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so it creates a counter clockwise moment
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so we put positive here
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so 28 multiplied by the distance x
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and the next moment is created by this
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force that is 40 kilo newton
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so it is going to be 40 multiplied by x
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minus 3
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minus because this force is going to
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create a
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clockwise moment about this section x so
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it is going to be minus
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and 48 multiplied by x minus 5
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so this is the bending moment about x
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and which is equal to
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e i d square y by d x square
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so we have considered some partition
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here
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to separate the section in the
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beam so this 28 x refers
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this section we have considered this
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section as one
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and the next section is cd
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so it is going to be the second section
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and the next one is this ac so this is
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going to be the third section
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and the corresponding moment value is
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given here so this representation will
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help us to find out the
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deflection at individual sections
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now we are going to integrate this
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equation with respect to k x
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to get the value of slope so
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by integrating this one we are going to
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get this value that is e
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i d y by d x is equal to 28
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x square by 2 plus c 1 this integration
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constant
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minus 40 x minus 3 whole power
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2 divided by 2 minus 48
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x minus 5 whole power 2 divided by
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2 so here also we can consider this
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partition that is 1 2 and 3
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now let us simplify the equation it is
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14 and it is
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20 and it is
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24. now let us write this simplified
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equation that is 14x square
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plus c1 minus john t
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x minus 3 whole power 2 minus 24
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x minus 5 whole power 2. here also
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we consider this partition 1 2 3 to
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represent the individual section in the
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beam so this equation is
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considered as equation number one
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now we are going to integrate this
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equation to get the
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deflection equation so by integrating
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the double equation
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we get e i y
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which is equal to 14 x cube divided by 3
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plus c 1 x
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plus c 2 so it is the second integration
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so we get the another constant which is
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called as c2 minus 20 x minus 3
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the whole power 3 divided by 3 minus
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24 x minus 5 the whole power 3 divided
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by
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3 let us simplify this equation
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which is 1 this is
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8 so the other time we will keep
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as it is okay so it is going to be 14
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divided by 3 x cube
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plus c 1 x plus c2 minus 20 divided by 3
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multiplied by x minus 3 whole power 3
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minus
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8 x minus 5 the whole power 3
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here also we have to consider this
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partition
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and this equation is referred as
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equation number
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two so we are going to use this equation
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to calculate
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the deflection at individual section and
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for that we need to calculate
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these two integration constants that is
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c1
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and c2 to find out the value of c1 c2
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we need to apply the boundary condition
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now we are going to see
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how to find the boundary conditions
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which are required to find out the c1
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and c2
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for that we need to consider this being
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here if i put x is equal to 0
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i am going to be here at the right
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support if i put x is equal to 0
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so when x is equal to 0 the deflection
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value is equal to 0
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the reason is at point b
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we have a simply support so when x is
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equal to 0 there is no deflection at
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this point
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since it is simply supported there is no
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motion along
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y direction so the deflection value is
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going to be zero
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similarly if i consider this point
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the x is equal to 6 meter i will be
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getting this point
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so when x is equal to 6 meter again the
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y value is going to be 0 because
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this end a is also simply supported so
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when x is equal to 6 meter y is equal to
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0. so these two are all the boundary
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conditions the first one is
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x equal to zero y is equal to zero this
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is boundary condition one
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and the second boundary condition is
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x is equal to six meter and y is equal
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to zero
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we are going to apply these boundary
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conditions to find out dc1
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and c2 that is x is equal to 0
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and y is equal to 0 and the second one
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is when x is equal to 6 y is equal to
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0 first let us apply the boundary
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condition
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1 in equation number
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2 so by substituting x is equal to 0
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and y is equal to 0 this term becomes 0
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and this term
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also 0 this term also 0
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and c2 is there and this
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tam is going to be 20 by 3 0 minus 3 the
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whole power 3 minus 8
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0 minus 5 the all power 3.
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now we are going to find out whether
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these two parts are needed or not
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so we have to be very careful about that
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because
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if any negative value is present
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within this bracket we should not
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consider that section
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the reason is when x is equal to 0 it is
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corresponding to the first part of the
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equation because here in the diagram you
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can see that
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when x is equal to 0 it lies in the
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point b so it represent the first
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section
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so we need to consider only the
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first portion so the remaining two
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portion
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we should not consider or otherwise we
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can remember like this
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if you get any negative value within
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this bracket
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we should not consider that part so the
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second part
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and the third part should not be
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considered because x is equal to 0
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which is only corresponding to this
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first part of the equation so we should
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not consider these two
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now by simplifying this equation we get
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c2 is equal to 0
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and the next boundary condition is when
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x is equal to 6 meter
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y is 0 we are going to substitute this
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boundary condition in equation number 2
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and we get the y value is 0
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and x value is substituted as 6
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so here we need to consider the all the
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part of the equation the reason is
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within the bracket we don't get any
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negative value
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and technically when x is equal to 6
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meter
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it represents the entire length so we
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need to consider the
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entire part of the equation first part
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second part as well as the third part of
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the equation
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so we need to consider the entire part
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of the equation when x is equal to 6
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meter
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so by simplifying this equation we got
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c1
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as minus 136.60
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now we have calculated the constants
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c1 and c2 let us substitute
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those values in equation number two
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c2 is zero so we don't consider that tam
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so here also we consider that three
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partition
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one two and three which represents
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different section of the beam this
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equation we represent that as
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equation number three now the deflection
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equation is ready to calculate the
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deflection at
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any point on the beam now we are going
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to calculate the deflection at
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d and deflection at c in order to find
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out the deflection at d
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we need to substitute x is equal to 3
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meter
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so in the equation number 3 we need to
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substitute x is equal to 3 meter
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to find out the deflection at this point
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d
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and if you want to find out the
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deflection at c in equation number 3 we
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need to substitute
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x is equal to 5 meter first let us find
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out the reflection at d
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to find out the deflection we need to
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substitute x is equal to 3 meter
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in the equation number 3 so by
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substituting this
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value we got e i y which is equal to 14
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by 3
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into 3 power 3 minus 136.67 multiplied
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by 3
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here we have applied the first part of
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the equation the reason is
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x is equal to 3 meter when x is equal to
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3 meter it lies
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in the first part of the beam so we need
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to consider the first
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part of the equation so we have
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considered the first part of the
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equation
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as x equal to 3 meter lies in the first
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part of the
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beam even if you substitute this value 3
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here it becomes 0 and this dam
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becomes negative within this bracket so
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we need to ignore these two
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terms by solving this terms
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we can get minus 2 eight four kilo
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newton
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meter cube since we have integrated this
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dam
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two times we got this dam as meter cube
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so the entire system represents
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in kilo newton meter cube we need to
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convert this dam into newton
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mm power 3 the reason is the x modulus
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value
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is given in newton per millimeter square
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and i value is given in millimeter power
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4. so we need to convert this dam into
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newton millimeter power 4
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so which is equal to minus 284 into 10
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to the power 12
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newton millimeter power 3 this dam
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is obtained by converting kilo newton
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into
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newton that is into 20 to the power 3
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multiplied by converting this meter into
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millimeter so
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10 power 3 the whole power 3 so
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totally we got 10 to the power 12 after
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converting this
00:17:19
unit into newton meter power 3
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we can substitute this value of e
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and i here so we got the y value as
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minus 16.7 mm this minus sign
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indicates the deflection happens below
00:17:36
the baseline
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after substituting x is equal to 3 meter
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we got that deflection at point d as
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16.7
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mm now let us calculate the deflection
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at c
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so if you want to find out the
00:17:52
deflection at c we need to substitute x
00:17:54
is equal to 5 meter in the equation 3
00:17:56
and here we have to consider only the
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first two part of the equation
00:18:02
because when you find out the deflection
00:18:05
at c
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the x is going to be 5 meter
00:18:11
it lies in the second part of the bin so
00:18:14
we need to consider the first
00:18:16
two part of the beam to find out the
00:18:18
deflection at
00:18:19
c so e i y which is equal to 14 by 3
00:18:24
multiplied by 5 power 3 minus 136.67
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multiplied by 5 and this is the second
00:18:31
term minus 20 divided by 3
00:18:33
5 minus 3 the whole power 3. even if you
00:18:36
apply the
00:18:37
3 here this third term becomes negative
00:18:40
so we have to
00:18:42
ignore this term so
00:18:45
by substituting the x in the
00:18:49
equation number three we got the values
00:18:51
minus 153.35 kilo newton meter cube so
00:18:56
we need to convert this kilo newton
00:18:57
meter cube into newton mm power 3
00:19:01
so that we can apply the value of e and
00:19:04
i
00:19:04
here so y is going to be minus
00:19:08
153.3 into 10 to the power 12 divided by
00:19:12
2 multiplied by 10 to the power 5
00:19:15
multiplied by 85 into 10 to the power 6
00:19:18
so the y value is minus 9.02
00:19:22
mm here also we got the negative sign
00:19:24
because
00:19:25
the deflection happened below the
00:19:27
baseline the deflection at c
00:19:29
is 9.02 mm
00:19:34
thank you for watching
