DE3329025A1 - Method and apparatus for determining the moisture content of cereal and other granular materials - Google Patents

Abstract

According to the method, the cereal or the granular material is placed in the electrical alternating field generated by a radio-frequency generator (3) between electrodes (2.1, 2.2, 2.3) of a leakage-field capacitor (2) and the current flowing through the leakage-field capacitor (2) is measured. The amplitude of this current depends on the capacitance of the leakage-field capacitor (2). This capacitance involves the permittivity of the cereal or of the granular material, especially that of its moisture content, and is a sensitive measure of the moisture content. The apparatus has a container (1) for the cereal or granular material on which a leakage-field capacitor (2) connected to a radio-frequency generator (3) is mounted. A current measuring device (4) is applied to the circuit consisting of radio-frequency generator (3) and leakage-field capacitor (2). <IMAGE>

Description

A-1/83 8.8.83 La./Kn.

Method and device for determining dfcs moisture content of grain and other granular substances.

The invention relates to a method and a device for determining the moisture content of grain and others granular substances according to the preamble of claims 1 or 2

Known methods for determining the moisture content of grain are the weighing-drying method or the conductivity method. Devices operating according to the last-mentioned method are known, for example, from a publication No.FM 1.0.0.17/11832 from Weiss Technik GmbH, Reiskirchen or a data sheet "Elektro-Schnel! Moisture meter HOH-EXPRESS HE 30 "from Ing.Franz Pfeuffer, Apparatebau, Kitzingen.

In the weighing and drying process, the grain must be ground, weighed, then dried in a drying room for at least 2 hours and then weighed again. That

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Procedure is very complex and practical only by specialists feasible in the laboratory. With the conductivity method the grain, as provided for in the known facilities, must be crushed and then placed in a measuring cell be pressed. Milling the grain makes it unusable for any further use. Also the conductivity method is very complex and cannot be easily performed by everyone. In addition, the measurement result very strongly influenced by the ambient temperature, the pressing pressure and the pH value.

A useful measurement of grain below 10% or above 30% moisture content is not possible with the conductivity method.

The object of the invention is therefore in particular to provide a method and a device for determining the moisture content of grain and granular substances, whereby the procedure can be carried out quickly and easily for everyone should, the grain or the granular material for carrying out the process can remain unchanged, so later is reusable, the measurement result is independent of the ambient temperature, the pressing pressure and the pH value, and finally the facility is characterized by a simple construction. This object is achieved according to the invention solved by the features of claims 1 and 2, respectively.

The advantages achieved with the invention can be seen, among other things, in the fact that an inherent moisture content between 0 and 50% is easy is demonstrable. Further advantages and features of the invention, as also characterized in the subclaims are, are explained below with reference to a preferred embodiment, with reference to the accompanying drawings Is referred to. In the drawing, a device according to the invention is shown in a single figure.

1 with a container is referred to in Figure 1, which the | Has the shape of an open-topped, cylindrical box with a flat, preferably made of insulating material bottom 1.1 ι . The container volume 1.2 is about half a liter to one liter. Electrodes 2.1, 2.2 and 2.3 of a stray field capacitor 2 are arranged on the underside of the bottom 2.2 of the container 1. The electrodes 2.1 and 2.2 are designed as concentric rings which encircle the electrode 2.3. The electrodes 2.1 and 2.3 are electrically connected to one another and lie in the same plane with the electrode 2.2. The stray field capacitor 2 is connected between the terminals of a high-frequency generator, namely the electrodes 2.1 and 2.3 together to one of the terminals and the electrode 2.2 to the other terminal. The high-frequency generator 2 generates an alternating electric field with a frequency in the range between the electrodes 2.1 and 2.3 on the one hand and the electrode 2.2 on the other hand

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from 100 kHz to 100 MHz, but preferably from 27.12 MHz corresponding to the natural frequency of a quartz crystal. Field lines of the alternating electric field between the electrodes 2.1, 2.3 and 2.2 are shown in the figure. Because of the chosen geometric arrangement of the electrodes 2.1, 2.3 and 2.2 penetrates most of the field lines the volume 1.2 of the container 1, so that the predominant part of the electrical field energy from the high-frequency generator 3 generated alternating electric field in the container volume 1.2, in particular in the lower half of the container volume 1.2 is included. In the circuit made up of the stray field capacitor 2 and the high frequency generator 3 there is also one Current measuring device 4 arranged. This consists of a circuit connected directly to the frequency of the High frequency generator 3 tuned series resonant circuit, from a capacitor 4.1 and an inductor 4.2. A voltmeter 4.3 is connected across the inductance 4.2 sen. The voltmeter 4.3 is preceded by a rectifier diode 4.4 and a smoothing capacitor 4.5 in parallel switched. Stray field capacitor 2, high frequency generator 3, the series resonance circuit from the capacitor 4.1 and the inductance 4.2, the rectifier diode 4.4 and the smoothing capacitor 4.5 are advantageously in a further one the container 1 attached container 5 and potted in its volume 5.1 in a synthetic resin and thus mechanically stabilized. Guide out of the container 5

Lines 4.3.1 and 4.3.2, the line 4.3.2 via a first switch 4.6, to the voltage measuring device 4.3. Close-1 I am at the container 1, but preferably below the j

Container 5, nor an electromagnetic vibrator 6, e.g.

again in a container 7, mechanically fastened. The J

I vibrator 6 is by means of a second switch 6.1 to a j

external alternating voltage 6.2 can be connected. The switches 4.6 j

and 6.1 are common, but in opposite directions from a time I

relay 8 can be actuated, which can be started manually by means of a pressure switch: 8.1.

To determine the moisture content of a grain or other granular substance, a sample amount is filled from above into the volume 1.2 of the container 1, it being sufficient to fill this approximately two-thirds full. Then the pressure switch 8.1 on the timing relay 8 is operated manually. The timing relay 8 then initially closes the switch 6.1 - at the same time opens the switch 4.6 - and thus sets the; Vibrator 6 in motion. Due to the shaking movements of the vibrator ' 6, the grain or the granular material settles in the container 1. After approx. 20 seconds. the time relay 8 switches off the vibrator 6 by opening switch 6.1 and at the same time closes switch 4.6. A direct voltage proportional to the amplitude of the current flowing in the circuit comprising the stray field capacitor 2 and the high-frequency generator 3 can now be read on the voltmeter 4.3.

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The size of the amplitude of the leakage field capacitor 2 The current flowing in the circuit from this stray field capacitor 2 and the high-frequency generator 3 depends, among other things, on the capacitance of the stray field capacitor 2. The dielectric constant of the grain or of the granular material. The dielectric constant of many solids, especially of completely dry grain, is less than 10, but that of water is about 81. Water contained in grain or granular material, the moisture, has an effect through its high dielectric constant very sensitive to the current amplitude. The current amplitude or the one proportional to it, from the voltmeter 4.3 displayed DC voltage can thus in an advantageous ι Can be used as a measured variable for the humidity.

Since the predominant part of the field energy of the electrical j alternating field between the electrodes 2.1, 2.3 and 2.2 of the Stray field capacitor 2 is contained in the lower part of the container volume 1.2, the voltage measuring device displayed DC voltage from a certain filling quantity, e.g. half the maximum filling quantity, practically independent of the sample amount used.

List of reference symbols

1 container for the grain or the granular material

1.1 Bottom of the container

1.2 container volume

2 stray field capacitor

2.1, 2.2, 2.3 Electrodes of the stray field capacitor

3 high frequency generator

4 current measuring device

4.1 condenser

4.2 inductance

4.3 Voltage measuring device 4.3.1, 4.3.2 cables

4.4 rectifier diode

4.5 smoothing capacitor

4.6 first switch

5 more containers

5.1 synthetic resin

6 vibrators

6 .1 second switch

6.2 AC voltage source

7 containers for the vibrator

8 timing relays

8.1 Pressure switch on the time relay

Claims (10)

A-l / 83 claims 1. ; Method for determining the moisture content of grain and other granular substances, characterized in that the granular substance is generated in a subfield containing the predominant part of the field energy of a stray field capacitor (2) between electrodes (2.1, 2.2, 2.3) of a high frequency generator (3) Brought electrical alternating field, which determines the current flowing through the stray field capacitor (2) and is used as a measured variable for the moisture content. / ίθ8. 2. Device for determining the moisture content of grain and other granular substances with a container (1) for the granular substance, characterized in that a Stray field capacitor (2) is provided, the is connected to a high frequency generator (3), in the circuit of high frequency generator (3) and stray field capacitor (2) a current measuring device (4) is arranged and electrodes (2.1, 2.2, 2.3) of the stray field capacitor (2) are arranged on the container (1) so that in the container volume (1.2) the majority of the electrical field energy of the electrical generated between the electrodes (2.1, 2.2, 2.3) by the high-frequency generator (3) Alternating field is included. A-l / 83 3. Device according to claim 2, characterized in that that the container (1) has the shape of a cylindrical can open at the top and the electrodes (2.1, 2.2., 2.3) outside the container volume (1.2) on the underside of the flat floor made of an insulating material (1.1) of the cylindrical can and are partially designed as concentric rings (2.1, 2.2). 4. Device according to one of claims 2 or 3, characterized characterized in that the high-frequency generator (3) between the electrodes (2.1, 2.2, 2.3) of the stray field capacitor (2) an alternating electric field with a frequency in the range from 100 kHz to 100 MHz, preferably from 27.12 MHz generated. 5. Device according to one of claims 2 to 4, characterized characterized in that the current measuring device (4) by a high-frequency generator (3) and in the circuit Stray field capacitor (2) arranged, tuned to the frequency of the high frequency generator (3), from one Capacitor (4.1) and an inductance (4.2) existing series resonance circuit, by a above the inductance (4.2) connected voltmeter (4.3), through a dem Voltage measuring device (4.3) upstream rectifier diode (.4) and through a to the voltage measuring device (4.3) parallel smoothing capacitor (4.5) is formed. A-l / 83 6. Device according to one of claims 2 to 5, characterized in that the container (1) is an electromagnetic Vibrator (6), again arranged in a container (7), is mechanically connected. 7. Device according to claim 6, characterized in that in series with the voltmeter (4.3) a first switch (4.6) and in one of the power supply lines of the electromagnetic vibrator (6), a second switch (6.1) is arranged and both switches (4.6, 6.1) each have an opposite switching state. 8. Device according to claim 7, characterized in that j the two ⁴ switches (4.6, 6.1) together from a time _; i relays (8) can be switched. 9. Device according to one of claims 2 to 8, characterized in that the container (1) has a volume (1.2) from about half a liter to a liter. 10. Device according to one of claims 2 to 9, characterized in that the stray field capacitor (2), the High-frequency generator (3), the series resonant circuit from the capacitor (4.1) and the inductance (4.2), the Rectifier diode (4.4) as well as the smoothing capacitor (4.5) in a further, attached to the container (1) The container (5) is arranged and its volume (5.1) is potted in a synthetic resin.