Minimum Order Quantity: 10 Set(s)
The design of a McLeod gauge is somewhat similar to a that of a mercury column manometer. Typically it is filled with mercury. If used incorrectly, this mercury can escape and contaminate the vacuum system attached to the gauge.
McLeod gauges operate by taking in a sample volume of gas from a vacuum chamber, and then compressing it by tilting, and infilling with mercury. The pressure in this smaller volume is then measured by a mercury manometer, and, by knowing the compression ratio, the pressure of the original vacuum can be determined. Boyle’s law is then used to find the initial pressure from the final pressure, and the initial and final volumes.
This method is fairly accurate for non-condensible gases, such as oxygen and nitrogen. However, condensible gases, such as water vapour, ammonia, carbon dioxide, and pump oil vapors may be in gaseous form in the low pressure of the vacuum chamber, but will condense when compressed by the McLeod gauge. The result is an erroneous reading, showing a pressure much lower than actually present. It has the advantage that it is simple to use and that its calibration is nearly the same for all non-condensable gases.
The device can be manually operated and the scale read visually, or the process can be automated in various ways. For example, a small electric motor can periodically rotate the assembly to collect a gas sample. If a fine platinum wire is in the capillary tube, its resistance indicates the height of the mercury column around it.
Modern electronic vacuum gauges are simpler to use, less fragile, and do not present a mercury hazard, but their reading is highly dependent on the chemical nature of the gas being measured and their calibration is unstable. For this reason McLeod gauges continue to be used as a calibration standard for electronic gauges.
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- Production Capacity: 100
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- Packaging Details: WOODEN BOX READY STOCK SAME.