Transcript Document

Experiment 2-2
Pressure versus Force
Experiment 2-2
Objectives:
1. Describe the relationship between pressure and force.
2. State Pascal’s Law and explain its application in fluid power.
3. Measure the force output of hydraulic cylinders using a load
spring.
4. Calculate the theoretical force output of a fluid power cylinder in
both extension and retraction.
Pressure Versus Force
In the above illustration, the load applies a downward force as
gravity pushes on it. The fluid inside the bottle, a liquid, resists
this movement by virtue of its incompressible nature and
pressure develops in direct proportion to the force applied.
Hydraulic Actuator Force Output
Rod End
Cap End
Double Acting Cylinder
Piston
Rod
Examine the picture above to become familiar with cylinder
nomenclature.
Hydraulic Actuator Force Output
Basic Cylinder Operation
Fluid moves from the pump or compressor outlet into the
cylinder by one of two or more ports. When the incoming fluid
makes contact with the piston, movement is created by the fluid
displacing the piston against the rod and, subsequently, moving
whatever load is in contact with the rod. It follows that some
relationship must therefore exist between how much a cylinder
can push based on how pressure is supplied to it.
Force, Pressure, and Area Relationship
Blaise Pascal was a 16th century mathematician, physicist, and
philosopher. He discovered the above relationship by observing the
effect that a trapped fluid had when a force was applied to it. The
result, a pressure buildup, is transmitted equally and at right angles
to all containing surfaces. What this means is that the behavior of
fluids is predictable. In the above illustration, known as the force
triangle, the amount of force is determined by multiplying P times A.
If one of the bottom elements is to be determined then you would
divide F by either P or A. This configuration is the same as Ohm’s
Law.
Calculating Force
F=PxA
Calculating force is accomplished by multiplying the pressure
value times the area value. Pressure is basically the force exerted
by the fluid against a moveable object, in most cases discussed, a
piston. Area is a two dimensional unit of measure, such as length
times width, and represents the total surface area on which
pressurized fluid acts. It is the combination of the pressurized
fluid acting on a moveable surface that results in force output.
Because the values of pressure and area are easily calculated, force
is easily calculated and very predictable. In operation, fluid is
forced into the cylinder by the pump where, upon contact with the
piston, it encounters resistance and pressure
Calculating Force
Cap End
Rod End
When calculating force on a “differential” style cylinder as shown
above, force must be calculated from two directions; extension and
retraction. Because of the greater surface area, the cylinder will
produce more force from the “cap end” than it will from the “rod”
end. When calculating the area of the rod end, first find the area of
the piston and then, the area of the rod. Subtract the rod area from
the cap end area and you will calculate the annular area.
Load Spring
CAUTION!!!
This experiment uses a compression spring that has a return force
of several hundred pounds. It is critical that instructions be
followed exactly during setup to prevent personal injury and
machine damage.
Load Spring
Examine the illustration above to see how the long rod is inserted
through the spring to cage it. The rod should have a threaded piece
which goes into the cam on the cylinder rod. When properly
inserted, there should be no visible thread between the cam and the
rod where the two attach. The main reason we are using this spring
is because it has a measured “rating” that can, in turn, be used to
measure force.
Spring Force Formula
Fls = (L – L1) X K
The formula above is based on a spring rate of 294
pounds per inch. What this means is that for every inch
you compress this spring, it will push back with a force
equivalent to the total amount of compression. For
example, lets say you have compressed the spring 2
inches, how much return force would you have? If you
multiply 294 times 2, the linear compression in inches,
you get 588 pounds of force. It should be obvious that
the spring represents a serious hazard if not properly
contained.
Theoretical and Actual Force
Theoretical force is the amount of force one would calculate
by simply using given values and applying Pascal’s Law.
Actual force is what one would calculate based on the
length of the load spring. It is meant for the two to be
compared and examined. As you read the instructions
please note that you will start with the large bore cylinder,
proceeding to the small bore cylinder. The only way to
compress the spring using the small bore cylinder is to
insert the spring behind the cam. This should become
obvious to you as you read the instructions.
Review
1. Describe the relationship between pressure and force.
2. State Pascal’s Law.
3. Calculate the force output on extension of a cylinder given the
following information.
Given:
Piston Diameter = 5 cm
Rod Diameter = 2 cm
Stroke Length = 28 cm
Pressure at Cap End = 6980 kPa
4. Calculate the force output of the cylinder in question 3 if the same
pressure is applied to its rod end.
Review
5. If the diameter of a cylinder’s piston increases, does the force
output increase, decrease, or stay the same?
6. If the pressure on a cylinder’s piston decreases, does the force
output increase, decrease, or stay the same?
7. If the length of cylinder’s stroke increases, does the force output
increase, decrease, or stay the same?
8. If the diameter of a cylinder’s rod decreases, does the cylinders
force output in retraction increase, decrease, or stay the same.
9. If the diameter of a cylinder’s rod decreases, does the cylinder’s
force output in retraction increase, decrease, or stay the same?
10. If a certain cylinder generates 2000 pounds of force at a pressure
of 250 psi, how much force would be generated if the pressure were
increased to 750 psi?
Review
11. If a cylinder with a 2 inch diameter piston requires 800 psi in
order to move a load, how much pressure would be needed if the
cylinder’s piston size were reduced to 1 ½ inches?
12. Why do actual and theoretical values differ?
13. Why does the small bore cylinder produce less force than the
large one?
14. What would be the result of increasing pressure on the small
bore cylinder.
15. How much return force would the load spring produce if it were
compressed by 3 inches?