DE20305448U1 - Assembly to measure the presence of suspended solids in a fluid pulped paper or cellulose - Google Patents

Abstract

An assembly determines the proportion of suspended solids in a liquid. The assembly has a container for the suspension, a dielectric measurement sensor which hangs in the liquid from an overhead support, and a data processing and read-out display. The assembly also esp. has a second sensor which measures the average density of the suspension, and which is also linked to the data-processing unit. The container is a length of pipe through which the fluid flows or a tank. The first sensor is a microwave emitter and detector which determines the dampening and/or phase transposition, or microwave time lapse. The second measuring probe is source of a gamma- o x-rays and an emission detector, operating in the range between 15 keV and 1.3 MeV. The measuring path is straight. The two sensors are located immediately side-by-side. A temperature sensor is located in the suspension and linked to the data processing unit.

Description

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Device for determining the solids content in a suspension

Description

The invention relates to a device for determining the solids content in a suspension according to the preamble of claim 1.

&iacgr;&ogr; In many industrial manufacturing processes it is important to measure the solids content in suspensions continuously, i.e. online. An important example of this is the paper industry, where the current solids content of paper or cellulose pulp is an important control variable.

A number of methods are known for determining the solids content in suspensions, the most important of which are briefly presented below:

The first possibility is to measure the density of the suspension. On the one hand, mechanical methods are known which are based on the measurement of shear forces, ultrasound measurement or the Coriolis principle. Furthermore, radiometric methods are also known which usually involve measuring the absorption of X-rays or gamma rays.

The methods based on density measurement have two basic disadvantages. Firstly, these methods are very sensitive to air bubbles in the suspension, as these shift the measurement result towards a solids content that is too low. Various methods are known to solve this problem, for example deaerating the suspension, measuring under high pressure, removing the air

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blowing through the action of a vacuum or compensating for the measurement error by an additional neutron measurement. A summary of these methods can be found, for example, in "On-Line Analyses of Coal" by Andrew T. Kirchner in IEA Coal research, September 1991. Although these compensation or correction methods generally lead to good results, they are very complex.

A fundamental problem with using density measurements to determine the concentration of suspensions is that they cannot be used for suspensions in which the density of the solid is essentially the same as the density of the liquid medium - usually water. This is the case, for example, with paper or cellulose pulps.

Another determination principle is based on measuring the dielectric properties of the suspension. This method is particularly suitable when the liquid is polar, for example water. These methods are based on the fact that most solids are non-polar and have a correspondingly lower dielectric constant than water. By determining one or more dielectric core variables, for example by determining the phase shift or the attenuation of a microwave, the solids content in a suspension can be determined.

This measuring method is also suitable for determining the solids content of paper or cellulose pulp, for example. Here, too, however, the problem arises that the measurement is significantly distorted by the presence of air bubbles, namely in that air bubbles are "interpreted" as solids due to their low dielectric constant, thus distorting the measurement result in the direction of too high a concentration. As already mentioned above, the removal of air bubbles is complex and often cannot be achieved at all in the main stream, so that a measurement can only be carried out in a side stream that has to be created specifically for this purpose.

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which of course leads to a correspondingly increased expenditure on equipment.

Based on this prior art, it is the object of the invention to provide a device for determining the solids concentration in a suspension, which can also be used for suspensions in which the specific gravity of the solids essentially corresponds to that of the carrier liquid, which can be used in the online process and requires relatively little equipment.

This object is achieved by a device having the features of claim 1.

First, the solids content of the suspension is determined in a known manner by determining at least one dielectric parameter. In general, the carrier liquid of the suspension is water and the fact that the solids suspended in water or another polar liquid have a significantly smaller ε is used here.

As already explained above, air bubbles in the suspension shift the measurement result in such a way that, without the appropriate correction, the measured solids content would be too high. A second measurement is therefore carried out to correct this error. According to the invention, this measurement is a measurement of the average density. The air bubbles in the suspension lead to a lower density of the suspension, so that this measurement can be used to correct the dielectric measurement. Since the density of the solids is often essentially the same as the density of the liquid medium, for example water, the density measurement as such is unsuitable for determining the solids content and can only be used in conjunction with the first process step to correct the measured value obtained there. It will often be useful to

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to continue to carry out a temperature measurement, since the dielectric properties of the suspension are usually strongly temperature dependent.

The dielectric properties of the suspension are preferably determined using a microwave measurement, whereby either the attenuation, the phase shift or both are measured. Depending on the measurement method, other measured variables can also be determined that are influenced by the dielectric properties of the material being measured, for example the transit time or quality and resonance shift of a resonator.

A gamma absorption measurement in the energy range above 60 keV or an X-ray absorption measurement is preferably used for density measurement. These measuring methods have the particular advantage that they do not require any mechanical components and are therefore very easy to maintain. The method according to the invention also has the particular advantage that it can be carried out online on a flowing medium. In particular, it is also possible to measure on the main production stream; laying bypass lines is not necessary. Even if the main area of application of the invention is seen in online measurement on flowing media, it should be emphasized that it can of course also be used offline and on stagnant suspensions.

Preferred embodiments of the device according to the invention emerge from the subclaims and from the embodiment now explained in more detail with reference to the figure.

Figure 1 shows a schematic representation of a device for measuring the solid content in a suspension.

The suspension to be measured flows through the pipe section 10. The first measuring probe in the pipe section 10 is a microwave sensor

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the microwave measuring section consisting of 22 and the microwave receiver 24. Such a measuring section is known, for example, from DE 42 11 362. Microwave transmitter 22 and microwave receiver 24 are connected to the evaluation unit 50 so that the attenuation and/or the phase shift of the microwave can be determined. Corresponding evaluation methods are known in the art.

The second measuring probe is formed by the gamma source 32 and the radiation detector 34, which are each located outside the pipe section.

&iacgr;&ogr; To prevent excessive gamma absorption, the pipe section 10 is preferably made of plastic. A C60, a CS-137 or an Am-241 source is suitable as a gamma source. If measurements are to be taken at lower photon energies, an X-ray tube is preferably used as the radiation source. The attenuation of the radiation and thus the average density of the medium being irradiated can be determined via this measuring section using known methods for a given geometry. The radiation detector 34 is also connected to the evaluation unit 50, where its measured values are used to correct the microwave measurements.

Preferably, the microwave measuring section and the X-ray measuring section are located in close proximity so that the air bubble content of the suspension is on average the same in both measuring sections. Furthermore, the pipe section 10 between the two measuring sections preferably has no curvature, since a change in the geometry could lead to a change in the air bubble content, which would make the measurement less accurate.

Furthermore, a temperature sensor 40 connected to the evaluation unit 50 is arranged in the pipe section 10 in order to be able to compensate for the temperature-dependent dielectric properties.

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A simple mathematical model is given below that can be used when the change in the dielectric properties of the liquid carrier medium is only changed relatively little by the presence of the suspended solid and the air bubbles. In this case, the influence of the solid and the influence of the air bubbles on the attenuation of the microwave can be considered as a small disturbance and a linearized approach can be chosen as follows:

Dmw = D ⁰ Mw + AipL + A ₂ Pf
&iacgr;&ogr; with:

Dmw = Attenuation of the microwave
D ⁰ Mw = basic attenuation
α = first coefficient
A ₂ = second coefficient

Pl = air bubble concentration
Pf = solid concentration

The basic attenuation caused by the water can be determined at different temperatures by a series of calibration measurements. This approach can be extended analogously by introducing the phase shift.

The deviation from this basic attenuation is caused by two thermals that depend linearly on the solid concentration and the air bubble concentration. The corresponding coefficients can be determined either by calibration measurements or theoretically.

So you first get a linear equation with two unknowns, namely the solid concentration and the air bubble concentration.

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The attenuation of gamma or X-rays is a measure of the average density of the medium being irradiated within the intended energy range for a given geometry. In most applications, a linear approach can also be chosen for the attenuation of the rays, whereby the basic attenuation is determined by the attenuation through the pipe walls and by the carrier fluid free of solids and air. With this approach, the attenuation of the radiation can be represented as follows:

Dr = D ⁰ R + A ₃ pL + A ₄ Pf
&iacgr;&ogr; with:

Dr = Attenuation of radiation
D ⁰ R = basic damping
A ₃ = third coefficient
A4 = fourth coefficient

Pl = air bubble concentration
Pf = solid concentration

The deviation from the basic attenuation is also derived from two linear terms which, as above, depend on the solid and air bubble concentrations. The coefficients can be determined by calibration or theoretically.

This gives us two linear equations, each with two unknowns, which can of course be solved.

Although this linearized approach will provide sufficiently accurate results in many cases, it is clear that other mathematical treatments, such as higher order perturbation approaches, can also be used. To increase the measurement accuracy, it is still

It is conceivable to measure the phase shift of the microwave in addition to the attenuation of the microwave.

Even though the measuring principle according to the invention has been explained primarily by determining the solids concentration in a paper or cellulose pulp, it is clear that this measuring principle can also be applied to other suspensions.

Claims (9)

1. Device for measuring the concentration of solids in a suspension with: - a receiving element for the suspension, - a first measuring probe arranged on or in the receiving element for measuring at least one dielectric characteristic of the suspension, - an evaluation unit, characterized in that a second measuring probe for measuring the average density of the suspension is arranged in or on the receiving element and is connected to the evaluation unit. 2. Device according to claim 1, characterized in that the receiving element is a pipe section through which the suspension flows. 3. Device according to claim 1, characterized in that the receiving element is a tank. 4. Device according to one of claims 1 to 3, characterized in that the first measuring probe is a microwave measuring section for determining the attenuation and/or the phase shift or propagation time of a microwave. 5. Device according to one of the preceding claims, characterized in that the second measuring probe consists of a gamma or X-ray source and a radiation detector. 6. Device according to claim 5, characterized in that the gamma or X-ray source emits gamma or X-rays in an energy range between 15 keV and 1.3 MeV. 7. Device according to claim 2 or according to one of claims 4 to 6, insofar as they relate to claim 8, characterized in that the pipe section runs straight between the two measuring probes. 8. Device according to claim 7, characterized in that the first and second measuring probes are arranged directly next to each other. 9. Device according to one of the preceding claims, characterized in that a temperature sensor for determining the suspension temperature is also provided and is connected to the evaluation unit.