DE3013437A1 - Measurement of surface gas mass flow in container - uses rotating sphere or cylinder in magnetic field - Google Patents

Abstract

The method is used for accurate measurement of the surface gas mass flow in a container. This is achieved without the use of temp. and pressure measurement. The measurement is made by recording the time variation in revolution rate of a body suspended in a magnetic field in the container and set in rotation. The body is of known density and size. For a sphere of known dia. the gas mass flow is related to the density, dia., and a time measurement.

Description

Method and device for determining the area-related

Gas mass flow p The invention relates to a method for Determination of the area-related gas mass flow p in a recipient.

The invention also relates to one for implementation device suitable for this measuring method.

According to K. Dieis / R. Jaeckel "Leybold-Vakuum-Taschenbuch", 2nd edition, 1962, Springer-Verlag, page 14, the area-related gas mass flow lu is the total mass of the molecules that move through a certain area in a certain time pass through, i.e. 1 -µ = ¼ nm # or 3 n: number of molecules per cm m: mass of a molecule in g: mean velocity of the molecules in cm sec -1 -2 p: pressure in dyn cm M: molecular weight of the gas in g mol T: absolute temperature The expressions too "Gas mass", "incident mass" or "incident mass flow" are common for the area-related gas mass flow. In the following, the brevity is used because of the expression gas mass.

According to the formulas mentioned, the gas mass p in a system can be determined by first determining the pressure and temperature in this system are measured and then the gas mass P according to the second of the formulas mentioned is calculated. The error of a result obtained in this way corresponds to thus the errors associated with temperature and pressure measurement.

The present invention is based on the object of a method to determine the gas mass r in a recipient, which is much more accurate and in which temperature and pressure measurement can be dispensed with.

According to the invention this object is achieved in that in itself known way, temporal changes in speed of a in the recipient in magnetic fields body of known density suspended in suspension and rotatable and size for calculating the gas mass P according to the formulas µ = a. r. lodge. n or 5 (t-to) no µ = a. d, = a5.

if the rotating body is a sphere, or µ = a. r. 1 lodge n or 2 (t-to) 2 + r / h no P = 77rh if the rotating body is a cylinder, measured will.

A: density of the rotating body r: radius of the rotating body Body d: diameter of the rotating body n: speed for Time t o n: speed at time t h: height of the cylindrical rotating body t is determined by the formula: 1 t2 tl 1 2 where t1 and t2 are measured one after the other Times are in which the rotating body makes a predetermined number of rotations.

Devices for the floating suspension of ferromagnetic bodies are z. B. from Rev.Sci.Instr., Vol. 44, No. 9, September 1973, known. About that In addition, it is also known to change the rotational speed of a suspended in a magnetic field Body to measure (DE-OS 15 73 603 and 21 19 838). Such measurements were previously used but only the pressure measurement in the respective system, which is additionally require a temperature measurement in the system. References to the present invention, so that the determination of the gas mass by measuring changes in speed is possible at all for suspended objects are the ones mentioned Documents cannot be removed.

A major advantage achieved by the present invention lies in the fact that the gas mass P can be determined very precisely. The formulas accordingly, the quantity P is an absolute value that is not obtained by calibration, but rather by weight (a), length (r, d) and speed (n ,, n) or time measurement (t, to) given is. Taking into account one of the surface of the rotating Body and the coefficient of friction depending on the gas type is not required if a maximum measurement error of 4 * can be accepted, since b only values between 0.98 and 1.04. As a rule, however, the value of t is at values between 1 and 1.02, so that p can be determined with an accuracy of 2%.

Another major advantage of the invention is that alone by measuring the gas mass P, a number of other state variables are already present in the recipient can be derived by simple calculation - i.e. with the same accuracy.

One of these state variables is z. B. the area-related gas particle flow (also incidence rate) ä of a gas, which is determined by the formula N 1 where denotes M: molecular weight of the gas and N: Avogadro's constant at the determination of the The incidence rate has been particularly recent in the context of surface physics special interest. From the rate of incidence one can refer to the one called 1 Langmuir Time to be closed, which is defined as the time that passes before the on particles impinging on a unit area form a monomolecular layer when they would all be adsorbed.

From P, the gas flow G can also be determined, which in a Connection line with any cross-section between two recipients with 1 and M2 prevails.

The following applies: G = (2) - d AR WR The following mean: AR: cross section of the connection Passage probability For a tubular connecting pipe applies: 4 dR WR 3. 1R with dR: diameter of the pipe 1R: length of the pipe.

Furthermore, with a known gas mass μ and additionally known Temperature and gas type in the recipient a number of other state variables by calculation be derived.

This is e.g. B. the density P, which is determined by Finally, the particle number density z is determined by the formula and the pressure p, determined by the formula derivable.

Further advantages and details of the invention are based on a Exemplary embodiment shown schematically in the figure for a device to carry out the measurement process are explained.

The figure shows a measuring chamber 1, within which a ball 2 in magnetic fields is suspended and can be rotated. Of those that generate the magnetic fields Devices are shown only two permanent magnets 3 and 4. Further, The position control and the rotational acceleration serving are not electromagnets shown. Only two coils 5 and 6 for measuring the speed of the ball 2 are visible. During the measurement, the measuring chamber 1 is in the affected one System or recipient in which the desired state variables are determined should. There is a sufficiently large connection through the opening 8 in the measuring chamber 1 with this system.

The pulses supplied by the coils 5 and 6 are a block 9 supplied counting device so that the speed of the ball 2 can be determined is.

With a device of this type, the gas mass P is in a system or Recipients can be determined. For this purpose, the ball 2 is activated by means of the acceleration magnets (not shown) brought to a certain speed. Then they are allowed to rotate freely. Through the Molecules hitting ball 2 reduce their speed of rotation. By determination the speed at two different times t and t or by determining different times Periods t1 and t2 in which the ball rotates a specified number of times, the gas mass can be determined using the formulas given. Additionally need only the density and the radius of the sphere 2 must be known.

Are also the type of gas in the system and the temperature known, then a number of other state variables such as rate of incidence å, Particle number density zt density f of the gas and also the pressure p by simple calculation derive.

In the context of the invention, it is particularly useful if the of the coils 5 and 6 supplied pulses to a computer, shown as block 10, are supplied, in which both the measuring methods and those specified by the Formulas specific calculation rules are stored. You also need this Computer 10 information on gas type (M) and temperature (T) can be entered. Finally, there is also the option of using the Type of gas and values for the coefficient of friction that depend on the material of the ball 2 b to be stored so that extremely precise measurements are possible.

With a device designed in this way, z. B. by Push a button (buttons 11) the various state variables in the system on a display device 12 represent. It is also possible to use several or all of the state variables at the same time to register by means of a writing instrument 14, so that a constant surveillance of the system is feasible with regard to its state variables.

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Claims (4)

Method and device for determining the area-related gas mass flow µ CLAIMS 1. Procedure for determining the area-related gas mass flow (or the gas mass) µ per unit of time and area in a recipient, characterized in that that in a manner known per se, temporal speed changes of one in the recipient Body suspended in magnetic fields and rotatable known density and size for calculating the gas mass P according to the formulas µ = a . r. lodge. n or 5 (t-to) no µ = a. d, 5 # if the rotating body is a ball is, or µ = a. r. 1 loge n / no or 2 (t-to) 2 + r / h µ = a. d. 1, P 2 tU 2 + r7h if the rotating body is a cylinder, be measured with the specified Signs have the following meanings: a: density of the rotating body r: radius of the rotating body d: diameter of the rotating body nO: speed of rotation for Time t 0 n: speed at time t h: height of the cylindrical rotating body and & is determined by the formula 1 = t2 - t1 # t1. t2, 1 = t2 - t1 # t1. t2, where t1 and t2 are successively measured times in which the rotating body makes a predetermined number of rotations. 2. Apparatus for performing the method according to claim 1, characterized characterized in that known devices for the floating suspension of a Body (2), to the rotational acceleration of this body (2) and to register its Speed are provided. 3. Apparatus according to claim 2, characterized in that for registration the speed of the body (2) a computer (10) is provided. 4. Device for determining the gas mass p and other state variables according to claim 2 or 3, characterized in that for registering the speed of the body, a computer (10) is provided in which the calculation formulas are stored and to which information about the temperature and type of gas in the system can be supplied, and that the various state variables can be selected by means of a display device (12) can be displayed or registered by means of a writing instrument (14).