DE384423C - Device for measuring high dilutions of gases and vapors - Google Patents

Description

The vacuum measurement is based in most cases on Boyle's law: p 'ν = const. In a measuring system, the gas, vapor, etc. to be measured is enclosed by the relevant degree of dilution at the time of measurement and compressed by a mercury column. The volume of the gas in the compressed state is read off and the pressure under which it is now results from the difference between the mercury levels in the measuring system and in a parallel riser pipe.

This method uses liquid mercury for compression. The measuring range - such vacuum gauge is simply be n

due to the quotient of the smallest compression volume ν to the total volume of the measuring system V. Since ν cannot be reduced below 10 cmm for practical reasons, because otherwise a reading is no longer possible, the decisive dimension for the measuring range is the volume V.

From the equation:

ν = V

η ■
follows for ν - 10 cmm =

1,

V = η

100,000

100,000

in liters.

So is the measuring range

he-

100,000

wishes, then V = 1 1 must be. At the same time, this is the upper practical limit of the measuring range, since 13 kg of mercury are required to meet an il volume. A measuring system of 101 with 130 kg of mercury is an impossibility, especially since the mercury has to be completely pure.

But even 13 kg of mercury in a measuring system is a large amount of dead capital. Hence concerned the following invention with a method and a device that basically dispensed with the mercury as a means of compression.

This is done in a simple manner that the compression by a solid Displacement body takes place, which is pushed into the measuring system.

Mercury is only used to seal against the outside atmosphere. It but could also be any other liquid with a sufficiently low vapor pressure (e.g. special vacuum oil) can be used. However, because mercury has the highest specific weight of all liquids in question, is the one required for sealing Barometer column the shortest, so that mercury is the most practical.

In Figs. 1 and 2, the method is shown on the basis of a schematically drawn vacuum gauge in the initial and final state of the measurement. The vacuum meter consists of two parts, which are self-contained, completely tap-free spaces, α is the fixed, the actual measuring system, b the movable part that forms the displacement body.

The measuring system is expediently a wide glass tube α with a connected capillary tube f, the wide one with a division approximately at * /. ,, ¹ I-, ¹ I ₁₉ , Vjooj the capillary tube with a diameter and a division of 100 graduation lines, so that one graduation line 10 mm ³ means volume. At c the riser pipe, which is fused to the measuring tube in an H-shape, branches off. At the bottom, both have a length which exceeds the column of the sealing liquid corresponding to the highest barometer level. This cuts at d

884423

Riser pipe at the level of the 'end of the measuring capillary f so that the surface is given a fixed height by overflowing into the ball. At the lower end of the sphere there is a very narrow hole in the riser pipe so that overflowing liquid can slowly run back as soon as the measurement is finished. Making such a hole is easy and flawless, as the reading only takes a few seconds

ίο lasts, during this time the altitude remains practically constant. The vessel e is only attached as a safety device to stop liquids that could shoot up if improperly handled (due to kinetic energy).

The displacement body consists of an inner tube b closed at the top and an outer tube A which is open at the top. The latter is expediently double-walled in order to use it as a dewar vessel for temperature control. A tip g sits on the tube b and serves to compress the capillary tube /. There is a tap i on the tube h to allow the dewar vessel to be emptied or a liquid to be evaporated to generate cold in it. In this way, even if part d is made of metal, any leakage that may be present due to the porosity of the pipe is rendered harmless. A thermometer k, which is immersed in the sealing liquid, is used to measure the temperature.

The vacuum gauge works as follows:

The measuring system is melted to the working area at A. As long as there is air in it, the sealing liquid in α and b is the same. If it is now emptied, it rises to below c, ie to barometer height. The height of the outer edge of A is dimensioned accordingly to accommodate the amount of liquid.

If measurements are to be taken, b is lifted using a suitable, well-centering lifting device so that the sealing liquid in the riser pipe d has reached the upper edge (Fig. 2). Read the graduation χ on the capillary tube and obtain the pressure

χ - mm Hg.

From the comparison, Fig. 1 and 2 is clear the fundamental advantage and contrast of the new process can be seen. One moves only the displacement body. The sealing liquid remains relative to the displacement body completely at peace. Only a fraction of it rises in the riser pipe. It is therefore also possible in a very short time Take measurements. While vacuum gauges with liquid displacement of ι 1 mercury takes about 1 minute to measure, and again 1 minute takes until you have re-established the connection, so that measurements can be made at best can take place in 3-minute intervals, the new method can take one every minute Measurement take place even if the measurement volume is more than 11.

Finally, it should be noted that in practice the following measurement limits are reached.

Measurement volume 11 10 ~ ⁵ mm Hg.
»10 1 10 ~ ⁶ mm Hg.

It is not advisable to go any further, as emptying the measuring volume will then take too long. After all, this means an extension of the previously customary measuring ranges of 10 * ~ ⁴ or ¹ Z _10,000 mm Hg. By a hundred times or two powers of ten. The big advantage, however, is the mercury saving and the speed of the measurements.

Claims (4)

Patent Claims: 1. Device for measuring high dilutions of gases and vapors using the compression of the gas to be measured, characterized by a solid, rigid displacement body (&) which can be introduced into the measuring chamber of the measuring system (a) and whose penetration into the measuring chamber causes the measurable compression of the gas to be measured is caused. 2. Device according to claim 1, characterized by a -barometric Column of liquid, in particular a column of mercury, which is used to seal the Measuring system (α) and the displacement body (&) against the atmosphere is used. 3. Device according to claim 1, characterized in that the displacement body (b) is surrounded by an appropriately double-walled vessel Qi) which contains the sealing liquid. 4. Device according to claim 1, characterized in that the double-walled vessel (A) is designed as a Dewar vessel or is provided with a vacuum valve (i) so that the sealing liquid can be kept cool or cooled by evaporation of liquid from the Dewar vessel Reduction of the vapor pressure of the sealing liquid. For this purpose ι sheet of drawings.