Fluke RUSKA 2470 User Manual

RUSKA 2470

Users Manual

2-2

S E CONDAR Y
PR E S S UR E

PR E S S UR E IN

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Figure 2-3. Controlled Clearance Cylinder

When the simple cylinder of 2-1 is subjected to an increase in pressure, the fluid, exerting

a relatively large total force normal to the surface of confinement, expands the cylinder

and thus increases its area. A pressure-drop appears across the cylinder wall near point A,

resulting in an elastic dilation of the cylinder bore.
It can be shown that the effective area of the piston and cylinder assembly is the mean of

the individual areas of the piston and of the cylinder; therefore as the pressure is

increased, the cylinder expands and the effective area becomes greater. The rate of

increase is usually, but not always, a linear function of the applied pressure. The piston

also suffers distortion from the end-loading effects and from the pressure of the fluid, but

to a much lesser extent than the cylinder. It is evident then, that the simple cylinder of 2-1

would be inadequate for a primary piston pressure gauge unless some means of

predicting the change in area were available.
The increase in the effective area of the simple cylinder is also accompanied by an

increase in the leakage of the fluid past the piston. Indeed, the leakage becomes so great

at some pressures that insufficient floating time can be maintained for a proper pressure

measurement.
In Figure 2-2, the pressure fluid is allowed to surround the body of the cylinder. The

pressure drop occurs across the cylinder wall near the top of the cylinder at point B, but

in the opposite direction to that of the simple cylinder in Figure 2-1. In consequence, the

elastic distortion is directed toward the piston, tending to decrease the area of the cylinder.
Again, the change in area with changing pressure places a limit on the usefulness of the

cylinder in 2-2 for it as a primary instrument. But some benefit results from the use of

this cylinder in the construction of a piston pressure gauge because higher pressures may

be attained without a loss in float time. A small sacrifice is made in the float time at

lower pressures because the total clearance between piston and cylinder must necessarily

be greater at low pressure for the cylinder in 2-2 than for the cylinder in Figure 2-1.
In the controlled-clearance design of Figure 2-3, the cylinder is surrounded by a jacket to

which a secondary fluid pressure system is connected. Adjustment of the secondary, or

jacket, pressure permits the operator to change the clearance between the cylinder and

piston at will. A series of observations involving piston sink rates at various jacket

pressures leads to the empirical determination of the effective area of the assembly.

Throughout the world, the controlled-clearance piston pressure gauge is an accepted

standard of pressure.
Piston pressure gauges having very high resolutions may be made by using simple and

reentrant cylinders. A determination of the distortion coefficients of such gauges may be

made by direct comparison with a controlled-clearance gauge. Most piston pressure

gauges have some elastic distortion, but some, used in the very low pressures, have only

small coefficients and, in some instances, correction for distortion may be neglected.