4.5.2: Pascal's Principle

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Page ID: 472546

Jamie MacArthur
Madera Community College

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Learning Objectives

Apply Pascal's Principle.

Most automobile shops are able to lift cars up using a hydraulic jack. Many manufacturing processes are dependent upon the hydraulic press. Both of these types of operation are based on pressure relationships within an incompressible fluid at rest. (By at rest, we mean that the fluid does not have a velocity.)

Blaise Pascal was a 17^th century French mathematician, scientist, and theologian. He discovered the relationship that these devices are based upon, and which we now call Pascal’s Principle.

Definition: PASCAL'S PRINCIPLE

A change in pressure at any point in an enclosed incompressible fluid at rest is transmitted equally and undiminished to all points within that fluid.

If we apply Pascal’s principle to a U-tube filled with a fluid, we can see how it is a useful concept. Each of the openings of the U-tube will experience the same pressure. If we add a force to one end of the U-tube, the pressure exerted by that force is dependent upon the area of the opening. If both openings have the same area, then an equal force will be exerted by the fluid at the other opening. If, however, the size of the openings are different, the area will be different, and therefore the force will be different. What remains the same is the pressure.

This principle can be very useful in multiplying the effect of a force. If the area of one side of the opening is half that of the other side, then a force exerted on the smaller area will be doubled on the other side. Similarly, if the difference in areas is a factor of 10, then the difference in forces will also be a factor of ten. This is the principle upon which the hydraulic press and the hydraulic lift are based. In a later chapter we will discuss simple machines and see that the effect of Pascal’s principle is very similar to the effect of a simple machine. In many cases, Pascal’s principle seems to be more easily applied in our modern technology than the simple machines we will discuss later.

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