Physics Of Bridges
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Physics of Bridges Norman Kwong Physics 409D
Forces
Before we take a look at bridges, we must first understand what are forces.
So, what is a force?
A force is a push or a pull
How can we describe forces?
Lets a take a look at Newton’s law
Newton’s Laws
Sir Isaac Newton helped create the three laws of motion Newton’s First law
When the sum of the forces acting on a particle is zero, its velocity is constant. In particular, if the particle is initially stationary, it will remain stationary.
“an object at rest will stay at rest unless acted upon”
Newton’s Laws Continued
Newton’s Second law
A net force on an object will accelerate it—that is, change its velocity. The acceleration will be proportional to the magnitude of the force and in the same direction as the force. The proportionality constant is the mass, m, of the object.
“F = mass * acceleration”
Newton’s Laws Continued
Newton’s Third law
The forces exerted by two particles on each other are equal in magnitude and opposite in direction
“for every action, there is an equal and opposite reaction”
So what do the laws tell us?
Looking at the second law we get Newton’s famous equation for force: F=ma m is equal to the mass of the object and a is the acceleration
Units of force are Newtons
A Newton is the force required to give a mass of one kilogram and acceleration of one metre per second squared (1N=1 kg m/s2)
So what do the laws tell us?
However, a person standing still is still being accelerated
Gravity is an acceleration that constantly acts on you F=mg where g is the acceleration due to gravity
So what do the laws tell us?
Looking at the third law of motion
“for every action, there is a equal and opposite reaction”
So what does this mean?
Consider the following diagram A box with a force due to gravity
So what do the laws tell us?
“for every action, there is an equal and opposite reaction” A force is being exerted on the ground from the weight of the box. Therefore the ground must also be exerting a force on the box equal to the weight of the box
Called the normal force or FN
So what do the laws tell us?
From the first law:
An object at rest will stay at rest unless acted upon This means that the sums of all the forces but be zero.
Lets look back at our diagram
The idea of equilibrium
The object is stationary, therefore all the forces must add up to zero Forces in the vertical direction: FN and Fg There are no horizontal forces
The idea of equilibrium
But FN is equal to – Fg (from Newton’s third law)
Adding up the forces we get FN + Fg = – Fg + Fg = 0
The object is said to be in equilibrium when the sums of the forces are equal to zero
Equilibrium
Another important aspect of being in equilibrium is that the sum of torques must be zero What is a torque? A torque is the measure of a force's tendency to produce torsion and rotation about an axis. A torque is defined as τ=DF where D is the perpendicular distance to the force F. A rotation point must also be chosen as well.
Torques
Torques cause an object to rotate
We evaluate torque by which torques cause the object to rotate clockwise or counter clockwise around the chosen rotation point
But what if the force isn’t straight?
In all the previous diagrams, the forces have all been perfectly straight or they have all been perpendicular to the object.
But what if the force was at an angle?
Forces at an Angle
If the force is at an angle, we can think of the force as a triangle, with the force being the hypotenuse
Forces at an Angle
To get the vertical component of the force, we need to use trigonometry (also known as the xcomponent) The red portion is the vertical part of the angled force (also known as the ycomponent Θis the angle between the force and it’s horizontal part
■
To calculate the vertical part we take the sin of the force ■
■
Fvertical
=F * sin (Θ)
Lets do a quick sample calculation Assume Θ=60o and F=600N ■ Fvertical = 600N * sin (60o) = 519.62N ■
Forces at an Angle ■ Like
wise, we can do the calculation of the horizontal (the blue) portion by taking the cosine of the angle ■ Fhorizontal ■ Fhorizontal
= F * cos (Θ)
= 600N * cos (60o) =300N
Bridges
Now that we have a rough understanding of forces, we can try and relate them to the bridge. A bridge has a deck, and supports Supports are what holds the bridge up
Forces exerted on a support are called reactions
Loads are the forces acting on the bridge
Bridges
A bridge is held up by the reactions exerted by its supports and the loads are the forces exerted by the weight of the object plus the bridge itself.
Beam Bridge
Consider the following bridge
The beam bridge
One of the simplest bridges
What are the forces acting on a beam bridge?
So what are the forces?
There is the weight of the bridge The reaction from the supports
Forces on a beam bridge
■
■
Here the red represents the weight of the bridge and the blue represents the reaction of the supports Assuming the weight is in the center, then the supports will each have the same reaction
Forces on a beam bridge
Lets try to add the forces
Horizontal forces (x-direction): there are none Vertical forces (y-direction): the force from the supports and the weight of the bridge
Forces on a beam bridge
Lets assume the bridge has a weight of 600N. From the sums of forces Fy = -600N + 2 Fsupport =0 Doing the calculation, the supports each exert a force of 300N
To meet the other condition of equilibrium, we look at the torques (τ=DF) with the red point being our rotation point τ= (1m)*(600N)-(2m)*(600N)+(3m)*(600N) = 0
Limitations
With all bridges, there is only a certain weight or load that the bridge can support
This is due to the materials and the way the forces are acted upon the bridge
What is happening?
There are 2 more other forces to consider in a bridge. Compression forces and Tension forces. Compression is a force that acts to compress or shorten the thing it is acting on Tension is a force that acts to expand or lengthen the thing it is acting on
There is compression at the top of the bridge and there is tension at the bottom of the bridge The top portion ends up being shorter and the lower portion longer A stiffer material will resist these forces and thus can support larger loads
Bridge Jargon Buckling is what happens to a bridge when the compression forces overcome the bridge’s ability to handle compression. (crushing of a pop can) ■ Snapping is what happens to a bridge when the tension forces overcome the bridge’s ability to handle tension. (breaking of a rubber band) ■ Span is the length of the bridge
How can deal with these new forces?
If we were to dissipate the forces out, no one spot has to bear the brunt of the concentrated force.
In addition we can transfer the force from an area of weakness to an area of strength, or an area that is capable of handling the force
A natural form of dissipation
The arch bridge is one of the most natural bridges.
It is also the best example of dissipation
In a arch bridge, everything is under compression It is the compression that actually holds the bridge up In the picture below you can see how the compression is being dissipated all the way to the end of the bridge where eventually all the force gets transferred to the ground
Compression in a Arch
Here is another look at the compression The blue arrow here represents the weight of the section of the arch, as well as the weight above The red arrows represent the compression
Arches
Here is one more look at the compression lines of an arch
A Stronger Bridge
Another way to increase the strength of a bridge is to add trusses What are trusses??
A truss is a rigid framework designed to support a structure
How does a truss help the bridge?
A truss adds rigidity to the beam, therefore, increasing it’s ability to dissipate the compression and tension forces
So what does a truss look like?
A truss is essentially a triangular structure. Consider the following bridge (Silver Bridge, South Alouette River, Pitt Meadows BC )
Trusses
We can clearly see the triangular structure built on top of a basic beam bridge. But how does the truss increase the ability to handle forces?
Remember a truss adds rigidity to the beam, therefore, increasing it’s ability to dissipate the compression and tension forces
Trusses
Lets take a look at a simple truss and how the forces are spread out
Lets take a look at the forces here Assumptions: all the triangles are equal lateral triangles, the angle between the sides is 60o
Lets see how the forces are spread out
■Sum of torques = (1m)*(-400N) + (3m)*(-800N) +(4m)*E=0 ■E=700N
■Sum of forces = AY + E - 400N - 800N ■Ay=500N
Now that we know how the forces are laid out, lets take a look at what is happening at point A Remember that all forces are in equilibrium, so they must add up to zero
■ ■ ■
Sum of Fx=TAC + TAB cos 60o = 0 Sum of Fy=TAB sin 60o +500N = 0 Solving for the two above equations we get ■
TAB = -577N
TAC = 289N
Compression and Tension ■TAB = -577N ■TAC = 289N ■The negative force means that there is a compression force and a positive force means that there is a tension force
Lets take a look at point B
■Sum of Fx = TBD + TBC cos 60o + 577 cos 60o= 0 ■Sum of Fy = -400N + 577sin60o –TBC sin60o=0 ■Once again, solving the two equations ■TBC =115N
TBD =-346N
Tension and Compression ■TBC =115N ■TBD =-346N The negative force ■The means that there is a compression force and a positive force means that there is a tension force
Forces in a Truss
If we calculated the rest of the forces acting on the various points of our truss, we will see that there is a mixture of both compression and tension forces and that these forces are spread out across the truss
Limitations of a Truss
As we can see from our demo, the truss can easily hold up weights, but there is a limitation.
Truss bridges are very heavy due to the massive amount of material involved in its construction.
Limitations of a Truss
In order to holder larger loads, the trusses need to be larger, but that would mean the bridge gets heavier Eventually the bridge would be so heavy, that most of the truss work is used to hold the bridge up instead of the load
Suspension Bridge ■Due to the limitations of the truss bridge type, another bridge type is needed for long spans ■A suspension bridge can withstand long spans as well as a fairly decent load.
How Suspension Bridge Works A suspension bridge uses the tension of ■A cables to hold up a load. The cables are kept under tension with the use of anchorages that are held firmly to the Earth.
Suspension Bridge ■The deck is suspended from the cables and the compression forces from the weight of the deck are transferred the towers. Because the towers are firmly in the Earth, the force gets dissipated into the ground.
Suspension Bridge ■The supporting cables that are connected to the anchorages experience tension forces. The cables stretch due to the weight of the bridge as well as the load it carries.
Anchorages ■ Each supporting cable is actually many smaller cables bound together ■ At the anchorage points, the main cable separates into its smaller cables ■ The tension from the main cable gets dispersed to the smaller cables ■ Finally the tensional forces are dissipated into the ground via the anchorage
Suspension Bridge Cable ■Here is a cross section picture of what a main cable of a suspension bridge looks like
A Variation on the Suspension ■A cable stayed bridge is a variation of the suspension bridge. ■Like the suspension bridge, the cable stayed bridge uses cables to hold the bridge and loads up
Comparison
Forces in a Cable Stayed ■A cable stayed bridge uses the cable to hold up the deck ■The tension forces in the cable are transferred to the towers where the tension forces become compression forces
Forces in a Cable Stayed ■Lets take a quick look at the forces at one of the cable points.
Forces in a Cable Stayed The “Lifting force” ■The holds up the bridge The higher the angle ■The that the cable is attached to the deck, the more load it can withstand, but that would require a higher tower, so there has to be some compromise
Limitations
With all cable type bridges, the cables must be kept from corrosion If the bridge wants to be longer, in most cases the towers must also be higher, this can be dangerous in construction as well during windy conditions “The bridge is only as good as the cable”
If the cables snap, the bridge fails
Forces
Before we take a look at bridges, we must first understand what are forces.
So, what is a force?
A force is a push or a pull
How can we describe forces?
Lets a take a look at Newton’s law
Newton’s Laws
Sir Isaac Newton helped create the three laws of motion Newton’s First law
When the sum of the forces acting on a particle is zero, its velocity is constant. In particular, if the particle is initially stationary, it will remain stationary.
“an object at rest will stay at rest unless acted upon”
Newton’s Laws Continued
Newton’s Second law
A net force on an object will accelerate it—that is, change its velocity. The acceleration will be proportional to the magnitude of the force and in the same direction as the force. The proportionality constant is the mass, m, of the object.
“F = mass * acceleration”
Newton’s Laws Continued
Newton’s Third law
The forces exerted by two particles on each other are equal in magnitude and opposite in direction
“for every action, there is an equal and opposite reaction”
So what do the laws tell us?
Looking at the second law we get Newton’s famous equation for force: F=ma m is equal to the mass of the object and a is the acceleration
Units of force are Newtons
A Newton is the force required to give a mass of one kilogram and acceleration of one metre per second squared (1N=1 kg m/s2)
So what do the laws tell us?
However, a person standing still is still being accelerated
Gravity is an acceleration that constantly acts on you F=mg where g is the acceleration due to gravity
So what do the laws tell us?
Looking at the third law of motion
“for every action, there is a equal and opposite reaction”
So what does this mean?
Consider the following diagram A box with a force due to gravity
So what do the laws tell us?
“for every action, there is an equal and opposite reaction” A force is being exerted on the ground from the weight of the box. Therefore the ground must also be exerting a force on the box equal to the weight of the box
Called the normal force or FN
So what do the laws tell us?
From the first law:
An object at rest will stay at rest unless acted upon This means that the sums of all the forces but be zero.
Lets look back at our diagram
The idea of equilibrium
The object is stationary, therefore all the forces must add up to zero Forces in the vertical direction: FN and Fg There are no horizontal forces
The idea of equilibrium
But FN is equal to – Fg (from Newton’s third law)
Adding up the forces we get FN + Fg = – Fg + Fg = 0
The object is said to be in equilibrium when the sums of the forces are equal to zero
Equilibrium
Another important aspect of being in equilibrium is that the sum of torques must be zero What is a torque? A torque is the measure of a force's tendency to produce torsion and rotation about an axis. A torque is defined as τ=DF where D is the perpendicular distance to the force F. A rotation point must also be chosen as well.
Torques
Torques cause an object to rotate
We evaluate torque by which torques cause the object to rotate clockwise or counter clockwise around the chosen rotation point
But what if the force isn’t straight?
In all the previous diagrams, the forces have all been perfectly straight or they have all been perpendicular to the object.
But what if the force was at an angle?
Forces at an Angle
If the force is at an angle, we can think of the force as a triangle, with the force being the hypotenuse
Forces at an Angle
To get the vertical component of the force, we need to use trigonometry (also known as the xcomponent) The red portion is the vertical part of the angled force (also known as the ycomponent Θis the angle between the force and it’s horizontal part
■
To calculate the vertical part we take the sin of the force ■
■
Fvertical
=F * sin (Θ)
Lets do a quick sample calculation Assume Θ=60o and F=600N ■ Fvertical = 600N * sin (60o) = 519.62N ■
Forces at an Angle ■ Like
wise, we can do the calculation of the horizontal (the blue) portion by taking the cosine of the angle ■ Fhorizontal ■ Fhorizontal
= F * cos (Θ)
= 600N * cos (60o) =300N
Bridges
Now that we have a rough understanding of forces, we can try and relate them to the bridge. A bridge has a deck, and supports Supports are what holds the bridge up
Forces exerted on a support are called reactions
Loads are the forces acting on the bridge
Bridges
A bridge is held up by the reactions exerted by its supports and the loads are the forces exerted by the weight of the object plus the bridge itself.
Beam Bridge
Consider the following bridge
The beam bridge
One of the simplest bridges
What are the forces acting on a beam bridge?
So what are the forces?
There is the weight of the bridge The reaction from the supports
Forces on a beam bridge
■
■
Here the red represents the weight of the bridge and the blue represents the reaction of the supports Assuming the weight is in the center, then the supports will each have the same reaction
Forces on a beam bridge
Lets try to add the forces
Horizontal forces (x-direction): there are none Vertical forces (y-direction): the force from the supports and the weight of the bridge
Forces on a beam bridge
Lets assume the bridge has a weight of 600N. From the sums of forces Fy = -600N + 2 Fsupport =0 Doing the calculation, the supports each exert a force of 300N
To meet the other condition of equilibrium, we look at the torques (τ=DF) with the red point being our rotation point τ= (1m)*(600N)-(2m)*(600N)+(3m)*(600N) = 0
Limitations
With all bridges, there is only a certain weight or load that the bridge can support
This is due to the materials and the way the forces are acted upon the bridge
What is happening?
There are 2 more other forces to consider in a bridge. Compression forces and Tension forces. Compression is a force that acts to compress or shorten the thing it is acting on Tension is a force that acts to expand or lengthen the thing it is acting on
There is compression at the top of the bridge and there is tension at the bottom of the bridge The top portion ends up being shorter and the lower portion longer A stiffer material will resist these forces and thus can support larger loads
Bridge Jargon Buckling is what happens to a bridge when the compression forces overcome the bridge’s ability to handle compression. (crushing of a pop can) ■ Snapping is what happens to a bridge when the tension forces overcome the bridge’s ability to handle tension. (breaking of a rubber band) ■ Span is the length of the bridge
How can deal with these new forces?
If we were to dissipate the forces out, no one spot has to bear the brunt of the concentrated force.
In addition we can transfer the force from an area of weakness to an area of strength, or an area that is capable of handling the force
A natural form of dissipation
The arch bridge is one of the most natural bridges.
It is also the best example of dissipation
In a arch bridge, everything is under compression It is the compression that actually holds the bridge up In the picture below you can see how the compression is being dissipated all the way to the end of the bridge where eventually all the force gets transferred to the ground
Compression in a Arch
Here is another look at the compression The blue arrow here represents the weight of the section of the arch, as well as the weight above The red arrows represent the compression
Arches
Here is one more look at the compression lines of an arch
A Stronger Bridge
Another way to increase the strength of a bridge is to add trusses What are trusses??
A truss is a rigid framework designed to support a structure
How does a truss help the bridge?
A truss adds rigidity to the beam, therefore, increasing it’s ability to dissipate the compression and tension forces
So what does a truss look like?
A truss is essentially a triangular structure. Consider the following bridge (Silver Bridge, South Alouette River, Pitt Meadows BC )
Trusses
We can clearly see the triangular structure built on top of a basic beam bridge. But how does the truss increase the ability to handle forces?
Remember a truss adds rigidity to the beam, therefore, increasing it’s ability to dissipate the compression and tension forces
Trusses
Lets take a look at a simple truss and how the forces are spread out
Lets take a look at the forces here Assumptions: all the triangles are equal lateral triangles, the angle between the sides is 60o
Lets see how the forces are spread out
■Sum of torques = (1m)*(-400N) + (3m)*(-800N) +(4m)*E=0 ■E=700N
■Sum of forces = AY + E - 400N - 800N ■Ay=500N
Now that we know how the forces are laid out, lets take a look at what is happening at point A Remember that all forces are in equilibrium, so they must add up to zero
■ ■ ■
Sum of Fx=TAC + TAB cos 60o = 0 Sum of Fy=TAB sin 60o +500N = 0 Solving for the two above equations we get ■
TAB = -577N
TAC = 289N
Compression and Tension ■TAB = -577N ■TAC = 289N ■The negative force means that there is a compression force and a positive force means that there is a tension force
Lets take a look at point B
■Sum of Fx = TBD + TBC cos 60o + 577 cos 60o= 0 ■Sum of Fy = -400N + 577sin60o –TBC sin60o=0 ■Once again, solving the two equations ■TBC =115N
TBD =-346N
Tension and Compression ■TBC =115N ■TBD =-346N The negative force ■The means that there is a compression force and a positive force means that there is a tension force
Forces in a Truss
If we calculated the rest of the forces acting on the various points of our truss, we will see that there is a mixture of both compression and tension forces and that these forces are spread out across the truss
Limitations of a Truss
As we can see from our demo, the truss can easily hold up weights, but there is a limitation.
Truss bridges are very heavy due to the massive amount of material involved in its construction.
Limitations of a Truss
In order to holder larger loads, the trusses need to be larger, but that would mean the bridge gets heavier Eventually the bridge would be so heavy, that most of the truss work is used to hold the bridge up instead of the load
Suspension Bridge ■Due to the limitations of the truss bridge type, another bridge type is needed for long spans ■A suspension bridge can withstand long spans as well as a fairly decent load.
How Suspension Bridge Works A suspension bridge uses the tension of ■A cables to hold up a load. The cables are kept under tension with the use of anchorages that are held firmly to the Earth.
Suspension Bridge ■The deck is suspended from the cables and the compression forces from the weight of the deck are transferred the towers. Because the towers are firmly in the Earth, the force gets dissipated into the ground.
Suspension Bridge ■The supporting cables that are connected to the anchorages experience tension forces. The cables stretch due to the weight of the bridge as well as the load it carries.
Anchorages ■ Each supporting cable is actually many smaller cables bound together ■ At the anchorage points, the main cable separates into its smaller cables ■ The tension from the main cable gets dispersed to the smaller cables ■ Finally the tensional forces are dissipated into the ground via the anchorage
Suspension Bridge Cable ■Here is a cross section picture of what a main cable of a suspension bridge looks like
A Variation on the Suspension ■A cable stayed bridge is a variation of the suspension bridge. ■Like the suspension bridge, the cable stayed bridge uses cables to hold the bridge and loads up
Comparison
Forces in a Cable Stayed ■A cable stayed bridge uses the cable to hold up the deck ■The tension forces in the cable are transferred to the towers where the tension forces become compression forces
Forces in a Cable Stayed ■Lets take a quick look at the forces at one of the cable points.
Forces in a Cable Stayed The “Lifting force” ■The holds up the bridge The higher the angle ■The that the cable is attached to the deck, the more load it can withstand, but that would require a higher tower, so there has to be some compromise
Limitations
With all cable type bridges, the cables must be kept from corrosion If the bridge wants to be longer, in most cases the towers must also be higher, this can be dangerous in construction as well during windy conditions “The bridge is only as good as the cable”
If the cables snap, the bridge fails
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