DE2149623A1 - METHOD AND ARRANGEMENT FOR MEASURING THE COMPOSITION OF SUBSTANCES - Google Patents

Description

Method and arrangement for measuring the composition of substances Often there is the problem, the density or the composition of a liquid, that flows through a pipe, for example, to measure continuously or at least changes to determine these values. To this end, methods can be used in which the liquid is irradiated with radioactive radiation and the absorption is determined in the liquid. For the measured intensity I the from which the The following equation applies: = I 9d - / u 9 d In this equation, 1o is the intensity in the absence of liquid, S is the density, d is the effective absorption path in the liquid and / u is the mass attenuation coefficient. The latter depends on the atomic number of the chemical contained in the liquid Elements and is therefore a measure of the composition of the liquid.

A measurement of the composition of a liquid after a such a method would not result in reliable measured values, because how can be seen from the above equation, the absorption also depends on the density of the Fluid is dependent. This dependency enables the density in in the same way as to measure the composition. But also those determined in this way Density values can be falsified as a result of a change in the composition0 Of the The present invention is based on the object of finding a method with which the density and the composition of liquids can be measured, without the measured values of one variable being falsified by changes in the other variable will. Furthermore, an arrangement for carrying out such a method is to be created will.

The solution to this problem was based on the idea that if one succeeds in finding a method with which only one quantity is measured in this way can be that the measurement results are independent of the other size, or the Measured values of this quantity checked with the unadulterated values of the other quantity can be and thus both sizes can be preserved unadulterated. It was recognized that the composition of a liquid can be measured independently of the density can. Likewise, the composition of powdery or granular material that z is transported on a belt.

The invention therefore consists in a method for measuring the composition of liquid, granular or powdery substances, which is characterized by the fact that the absorptions of two radioactive radiations of different quantum energies measured and the ratio of the logarithms of the absorptions is formed. For the absorption measurements are once after the intensities of the two radiations Passage through the vessel containing the substance and another time after passage measured the empty vessel. The following apply to the intensities of the two radiations Relationships: 1.) I1 = I01 e / U1 d1 2.) I2 ~ I02 e; U2 9 d2 in these equations Iq and I2 mean the measured intensities of the radiation emerging from the vessel, if this is filled with the substance, I01 and Iõ2 the intensities if the vessel is empty, / u1 and / u2 are the absorption coefficients for the two radiations and d1 and d2 are the effective absorption paths. The latter are almost the same. If one forms the ratio of the intensities of each radiation measured with and without substance, logarithinizes this ratio and then forms the ratio of the logarithms, for this one obtains the relation: ln I01 - ln I1 µ1d1 µ1 Q = ln I02 - ln I2 = µ2d2 ~ µ2 The quantity Q is independent of the density. The absorption in the vessel walls was not taken into account because it remains constant and therefore only in size Q occurs as a constant.

Appropriately, preparations are used as the radiation source, of which one a gamma radiation with a quantum energy of less than 100 keV and the other emits gamma radiation with a quantum energy of more than 500 keV. This is because the mass attenuation coefficient is for radiation energies of less than 100 keV strongly dependent on the chemical atomic number, while with a radiant energy of more than 500 keV this dependency is low. Suitable radiations are e.g. the 60 keV radiation from Am 241 and the 660 keV gamma radiation from Cs 137. With such Preparations one obtains a strong dependence of the quantity Q on the effective chemical Ordinal number and thus a high measuring sensitivity.

The new method is suitable, for example, for using a liquid with no constant density to monitor their composition. Such density changes can be caused by temperature fluctuations in the liquid at the point of use. In such a case, the quantity Q can be used for measuring and, if necessary, also for regulating a metering device used for one or more components will.

With the new method, one more problem can be solved, mainly occurs in chemistry, especially petrochemistry and food chemistry. This problem is to continuously measure the density of a liquid or to regulate, with undesirable changes in the composition or with impurities must be expected from substances with a different ordinal number. The density can e.g. can be controlled in that with the help of a metering device a density-changing Addition of the liquid is mixed. To solve this problem is the intensity the softer radiation emerging from the liquid is used to measure the density. In addition, the quantity Q is used to issue a warning. As long as only pure Dicate changes are present and the size Q is within specified limit values control is normal. But as soon as such a chemical change or contamination occurs that the quantity Q exceeds or falls below a limit value, a warning signal is triggered and, if necessary, production is shut down until the error has been eliminated. Before the actual measuring or control process can also as in all other applications of the new process, the system uses a standard liquid be calibrated. Of course, the one that changes the density of the liquid influences Addition also their composition. By suitable choice of the elements of the addition this influence can be kept small that the specified limits for the Composition not to be exceeded.

With reference to the drawing, the invention and others are described below Advantages and additions described and explained in more detail.

FIG. 1 shows the absorption of gamma radiation as a function of speed of the atomic number, Bigur 2 an arrangement for irradiating a liquid with gamma rays of different energies and FIG. 3 shows a circuit arrangement for evaluating the signals generated with the arrangement according to FIG.

In Figure 1 is the dependence of the mass attenuation coefficient for gamma rays of different energies depending on the atomic number Z shown. The ordinal number Z is plotted on the abscissa, while in the ordinate direction the mass attenuation coefficients are plotted in cm -1. The solid one The curve labeled / u1 shows the mass attenuation coefficient of 60 keV gamma radiation von Am 241. The curve begins at an ordinal number Z = 10 with about 0.2 cm 1, increases then steadily increases and reaches an ordinal number of over 5 cm-1 at ordinal number 50 Value. The dashed curve labeled / u2 shows the course of the mass attenuation coefficient for the 0.66 MeV radiation from Cs 137. This is about 0.1 cm, which is considerably lower than that of the 60 keV radiation and is also roughly constant. The dash-dotted line marked Q indicates the course of the relationship the mass attenuation coefficients / U1 and / U2. The values for the Q size are plotted on the right edge of the diagram in the ordinate direction. The size Q shows a steep course, is therefore strongly dependent on the atomic number and thus on the chemical one Composition of the irradiated material depends.

The two radioactive preparations from Am 241 and Cs 177 are suitable Especially for measuring and checking compositions, their components are atomic numbers to have, that are smaller than 55. For higher ordinal numbers you can in particular, instead of Am 241, other preparations are used, whereby on it care must be taken that the mass attenuation coefficient / u1 is in the Ordinal number range has a steep course and the curve for the mass attenuation coefficient / U2 runs as flat as possible. In FIG. 2, 4 denotes a tube through which a liquid flows, its composition and possibly also density measured shall be. For this purpose, the absorption of the gamma rays by two radioactive Preparations 1 and 2 measured, one of which is soft and the other one emits hard gamma rays.

For example, one preparation can be Am 241 and the other Cs 137 contain. The two preparations are in a protective container 3, which the Shields the outside space from the specimens. On the one opposite the specimens Side of the tube 4 is a detector that emits electrical impulses whose Height are proportional to the quantum energy of the incident radiation. In the exemplary embodiment this detector consists of a scintillation crystal 6 to which a photomultiplier 7 is connected. In front of the detector is a conical hole or slit collimator 5 made of heavy metal, so that the influence of diffuse scattered radiation (Compton radiation) from the material to be measured is low. The detector is located in a housing 8 made of heavy metal, that shields it from radiation and thus reduces the background effect. Instead of the scintillation crystal selected in the exemplary embodiment and the one connected downstream of it Secondary electron multiplier can also be another proportional mjetektor, E.g. a lithium drifted silicon detector can be used.

In special cases, preparations 1 and 2 can be spatially separated be attached, and a detector can be assigned to each preparation. In this Case the detector does not have to work proportionally. Should the composition of powdery or granular material that is transported on a belt, measured are expediently-the radiation source and the detector under or. above of the tape arranged.

The output pulses of the photomultiplier 7 are in the circuit arrangement further processed according to FIG. You first get into one after pre-amplification Amplifier 9, from the output of which they are distributed to two channels. Any channel contains at the input a discriminator 10 or 11, one of which, 10, on the Pulse height is set, which occurs when a photon arrives from preparation 2 the detector 7 arises. The detector 11 is correspondingly at the level of the pulses set, which are generated when photons of the other radiation arrive. if two different detectors are used, no discriminators are required.

Counters 12 and 13 are connected to discriminators 10 and 11, which the output pulses of the discriminators during one of a timer 14 add up the given time. The count results are in units of 15 and 16 logarithinated. These are followed by two units 17, 20 or 18, 21, to which the output variables of the units 15 and 16 can optionally be fed. The units 20 and 21 are 3 memories in which the values are stored before a measurement which are determined when the pipe 4 is empty. So they are the logarithms of Intensities 101 and 102 respectively. After these first files are saved and with the actual Measurement is bcgomten, the subtraction elements are sent to outputs 15 and 16 17 and 1d are connected each time they receive a value from the units 15 and 16 ugeS: what is learned is the difference these values with the in the memories 20 and 21 contained T: erten form. rus the differences make one Dividing member 19 the desired size Q, which is independent of the density of the Meffigut is.

Should simultaneously with the measurement of the composition of the liquid, aTso the quantity Q, the density can be measured, so this can be from the counter 12 or the signals emitted by the logarithmic element 15 are determined which correspond to the absorption correspond to the harder radiation.

10 claims 3 figures

Claims (10)

Method for measuring the composition of liquid, powdery or granular substances, characterized in that the absorptions of two radioactive radiations of different quantum energies measured and that Ratio of the logarithms of the absorptions is formed. 2. Arrangement for performing the method according to claim 1, characterized characterized in that two radioactive emitters (1, 2) on one side of the one Liquid containing vessel (4) are attached and that on the opposite Side a selective detector (6, 7) arranged for the radioactive radiation is. 3. Arrangement according to claim 2, characterized> that between Liquid (4) and detector (6) are directed at the radioactive preparations (1, 2), Conical hole or slit collimator (5) made of heavy metal is attached. 4. Arrangement for carrying out the method according to claim 1, characterized in marked that two spatially separated radioactive radiation sources are provided, each one on the opposite side of the liquid containing vessel attached detector is assigned. 5. Arrangement according to one of claims 2 to 4, characterized in that that the one preparation (1) emits a soft gamma radiation of less than 100 keV, e.g. 60 keV, and the other (2) hard gamma radiation greater than 500 keV, e.g. 660 keV, emits. 6. Arrangement according to one of claims 2 to, characterized in that that one preparation consists of Am 241 and the other of Ca 137. 7. Arrangement according to claim 2 or 3, characterized in that on the output of the selective detector (6, 7) two discriminators (10, 11) connected are, of which one is at the level of the output pulses that are received upon receipt of the one radioactive radiation arise, and the other on the level of the pulses that occur at Receiving the other radioactive radiation is discontinued. 8. Arrangement according to one of claims 2 to 7, characterized in that that each detector or each discriminator (10, 11) is followed by a counter (12, 13) is that the input pulses during a given by a timer (14) Time summed up that the counter (12, 13) is followed by a logarithmic element (15, 16) is that a memory (20, 21) can be connected to the logarithmic element (15, 16), that a subtraction element (17, 18) is provided that the difference between that in the memory (20, 21) contained q-MeSt and the output signal of the logarithmic element bil et and that the subtraction members (17, 18) are followed by a dividing member (19) is. 9. Application of the method according to claim 1 for measuring the density a liquid, characterized in that the absorption of radiation, preferably that of the softer radiation, is used as a measure of the density and the measurement is corrected if a change in composition is measured at the same time. 10. Application of the method according to claim 1 for regulating the density " a liquid, characterized in that as a function of the measured absorption radiation, an addition of the liquid which changes the density of the liquid is mixed and that with a change in the composition of the liquid a fault report is issued.