CS227666B2 - Digital meter of humidity - Google Patents

Description

The invention relates to a digital moisture meter, in particular for determining the moisture content of cereals and other powdered, granular or granular materials, provided with a sensing unit, a control circuit, a boost stage, a gate counter and a display unit.

Devices are known for rapidly detecting the moisture content of a variety of granular and pulverulent materials, in particular grains. The function of these known devices is generally to determine the dielectric constant of the measured material. The dielectric constant is determined by measuring the capacity of the measuring cell with the measured mass using high-frequency alternating voltage

The aforementioned devices include, for example, modified Colpitt oscillators (see, for example, Maarial Patent No. 154,475), Hartley oscillators (see, Hungarian Patent Specification, 148,670 and United States Patent No. 3,761,810), high-frequency measuring bridges (see U.S. Pat. No. 3,691,457 and 3,566,260).

The radio frequency measurement method is also used in the apparatus of U.S. Patent Nos. 3,559,052 and 3,596,176.

Measuring circuits in which high frequency AC voltage is used, such as oscillators, measuring bridges, contain a large number of discrete components, such as resistors, capacitors, transistors, and therefore the manufacture, adjustment, calibration and repair of such devices is very costly. High-frequency ICs are not known, realization of digital ICs having favorable characteristics is not possible.

High-frequency measuring circuits, made up of discrete elements, can only be adjusted with difficulty to digital correction and digital imaging circuits.

Further, methods and devices for rapidly detecting the moisture content of grain and other granular or pulverulent materials are known, such as the method described in German Laid-Open No. 1,234,052 using magnetic nuclear resonance, neutron or microwave absorption, but these are now From the point of view of practice, it is insignificant both for their insufficient accuracy and for their uneconomical feasibility.

The dielectric constant of any material, such as grain, depends not only on the moisture content but also on a number of other factors, the most important of which are the measuring frequency, the temperature of the material to be measured and the density. The dielectric constant 8 decreases in frequency, increases exponentially with temperature and increases almost linearly with density.

High-precision measuring devices are provided with an automatic temperature compensation circuit, such as those described in U.S. Pat. No. 3,761,810 using a thermistor and a thermocouple as the thermal sensor.

Moreover, this apparatus is the closest to the present invention. The instrument contains a sensing unit equipped with a mechanical scale, a high-frequency Hartley oscillator, a frequency meter equipped with a control unit, a gate counter and a display unit.

The disadvantage of a thermistor, generally used after temperature sensing, is its rapid aging, displacement characteristic and non-linearity. The disadvantage of the thermocouple is the high cost of the requirements of the measuring amplifier connected to it.

It is an attempt to ensure the reproducibility of measurements in the apparatuses described in said patents by weighing samples of equal weight. However, the measurement accuracy is unsatisfactory with cereals, especially maize, since the size, bulk density and grain arrangement of the measuring cell are varied, thereby adversely affecting the measurement accuracy. The situation is also complicated by the fact that the density depends on the moisture content.

These disadvantages are eliminated with the digital humidity meter according to the invention, which consists in that the output of the moisture content of the sensor unit is connected to the first input of the RC pulse generating circuit, the output of the sensor temperature values is connected to the second input of the RC pulse generating circuit and the output weight sensor unit output is connected to the amplifier stage input, the amplifier stage output is connected via a controllable generator to the first input of the first product circuit, the output of the control circuit is connected to the third input of the RC pulse generating circuit, pulses, with the first input of the first counter and the first input of the linearizing circuit, the output of the RC pulse generating circuit is connected to the first input of the differential circuit, the output of the RC pulse generating circuit is coupled to the second input of the difference the output of the differential circuit is connected to the second input of the first product circuit, the output is connected to the second input of the first counter, and the output of the first counter is connected to the second input of the linearizing circuit, the pulse output of the linearizing circuit is connected to the reverse counter input of the first counter. and the linearizing circuit data output is connected to the display unit input.

In a preferred embodiment of the digital humidity meter according to the invention, the sensing unit comprises a measuring cylinder, a capacitive measuring unit, a weighing unit and a temperature measuring unit, the measuring cylinder is arranged with its openable bottom above the capacitive measuring unit. the unit is mounted on a weighing unit, the output of the capacitance measuring unit being connected to the first input of the RC pulse generating circuit, the output of the temperature measuring unit is connected to the second input of the RC pulse generating circuit, and the output of the weighing unit is connected to the amplifying stage input.

The invention makes it possible to economically manufacture easy-to-use and more accurate digital moisture meters, since their method of measurement is based on time measurement, is free from polarity changes and is compensated by volumetric weight. An exemplary embodiment of a digital moisture meter according to the invention is shown in the accompanying drawings, in which Fig. 1 is a block diagram of a digital humidity meter, Fig. 2 shows the composition of the pulse generating circuit HC, and Fig. 3 shows the linearizing circuit.

The sensing unit 1 according to FIG. 1 consists of a measuring cylinder g, a capacitive measuring unit J which consists of a cylinder, a rod preferably arranged coaxially with the cylinder and to ensure a uniform distribution of material conical, insulated from the cylinder and mounted on the weighing unit , £, and from the temperature measuring unit 2, which is arranged inside the capacitive measuring unit 2,

The output of the moisture content of the sensor unit 1 is connected to the first input of the RC 6 pulse generating circuit, and the second input is connected to the output of the temperature unit of the sensor unit J. RC 6 for pulse generation. The difference between the pulse proportional to the capacity of the capacitive metering unit 2 and the temperature-corrected pulse and the pulse proportional to the zero moisture content is formed in the differential circuit 2 at the command of the control circuit 2. circuit 2 through the first product circuit 12 permits. The counter of the output signal of the controllable generator 11 is corrected in the weighing unit 6, the output being the output of the volumetric mass sensor unit 1. The correction is effected via the amplification stage 10 as it corresponds to the relationship between the dielectric constant and density. The linearizing circuit 14 linearizes the corrected function of the dielectric constant (moisture content). In this way, the numerical value appearing on the display unit 15 shows the moisture content of the material inserted in the measuring cylinder 2.

The digital moisture meter according to the invention operates as follows.

The material to be measured is filled ^{with an} opening bottom measuring cylinder 2 which ensures a constant sample volume during the measurement. When the measuring cylinder 2 is opened, the material enters the capacitive measuring unit 2 under the influence of gravity.

By applying a pulse to the input of the control circuit 2, this first counter 13 sets to zero, then, after reaching a constant temperature of the temperature measuring unit g, the pulse circuit RC 6 and the base pulse circuit RC g are excited.

The action of the RC 6 pulse generating circuit is shown in FIG. 2,

A generator composed of monostable multivibrators 16 and a first divider 18 are used to excite the proportional RC pulse. corresponding temperature coefficient. On the start signal of the control circuit 2 ae, the first divider 18 is set to zero and a generator consisting of monostable multivibrators 16 generates pulses of the aforementioned width. At the output of the first divider, a pulse appears which has a width multiplied by the attenuation ratio by means of the second product circuit 17 and the inverter 12 and is proportional to the capacity of the capacitive metering unit.

The timing of the base pulse generating circuit RCg, which preferably consists of a monostable multivibrator, is set so that the pulse width corresponds to the pulse width RC pulse generating circuit when a zero moisture material is contained in the capacitive metering unit 2. In this way, the pulse generated at the output of the differential circuit 2 is proportional to the temperature-corrected moisture content of the material contained in the capacitance measuring unit 2. The numerical value proportional to the pulse width thus obtained is determined by the controllable generator 11 and the first product circuit 12 in the first counter 13.

The pulse repetition period of the controllable generator 11 is selected to correspond to the bulk density of the material to be measured. The determination of the bulk density of the material whose constant volume is provided by the measuring cylinder 1 is carried out in the weighing unit 6.

As can be seen from FIG. 1, the weighing unit 1 is formed by an unbalanced bridge, preferably composed of four strain gauges, the output voltage being proportional to the weight thereon and to the capacitive measuring unit. The voltage is amplified in the amplification stage 12 in a ratio that corresponds to the function of the dielectric constant / density of the measured material. The output of the amplification stage 10 is connected to a controllable generator 11, wherein the output signal is proportional to the bulk density of the material to be measured.

The readout of the signal of the controllable generator 11 provides a corrected value of the measured moisture content for temperature and bulk density, the duration of the pulse width reading being equal to the pulse width of the differential circuit 2.

In general, the dependence of the dielectric constant on the moisture content is not linear for various materials, in particular cereals, in the measurement method described above, so direct display of the output information of the first counter 13 would not be advantageous.

As can be seen from FIG. 3, the linearizing circuit 14 linearizes the function of the dielectric constant / moisture content according to the type of material. Essential in this action is that the inverse of the function to be linearized is approximated by straight sections whose steepness is contained in the memory 24. The pulse train carrying the measurement information arrives at the forward count input of the first counter 13, wherein at the end of the measurement In the process, a linearized function appears at its output. Now, the signal coming from the control circuit 1 and passed to the comparative input E of the third product circuit 25 starts to calculate the corresponding value of the linearized function, so that the generator 21 signals pass through the third product circuit 25 and preferably set the second divider 20 and via a programmable divider 22 to the input of the second counter 23.

In this way, the content of the counter 13 decreases until the value of Y _Q passed to the comparator input 26 is reached, wherein Y _Q denotes the value of the linearized function at the zero point of the independent variable. Now the comparator 26 closes the third product circuit 25 and the value of the linearized function is available at the output of the second counter 43. The attenuation ratio of the programmable divider 22 results from the value present at the output of the second counter 22 as the steepness of the inverse function changes. The output of the second counter 23 is connected to the display unit 22 and / or to the signal processing units.

Claims (2)

SUBJECT OF THE INVENTION A digital moisture meter, in particular for determining the moisture content of cereals and other powdered, granular or granulated materials, having a sensing unit, a control circuit, a boost stage, a gate counter and a display unit, characterized in that 1) is connected to the first input of the RC (6) pulse generating circuit, the temperature output of the sensor unit (1) is connected to the second input of the RC pulse generating circuit (6) and the output volumetric weight value of the sensor unit (1) is connected to input of the amplification stage (10), the output is connected via a controllable generator (11) to the first input of the first product circuit (12), the output of the control circuit (7) is connected to the third input of the RC circuit (6) the RC (8) circuit for generating the base pulses and, on the other hand, with the first input of the first counter (1 3) and with the first input of the linearizing circuit (14), the output of the circuit The pulse generating RC (6) is connected to the first differential circuit input (9), the base pulse generating RC (8) is connected to the second differential circuit input (9), the differential circuit output (9) is connected to the second input a first product circuit (12), the output of which is connected to a second input of the first counter (13), the output of which is connected to a second input of the linearizing circuit (14), the pulse output of the linearizing circuit (14) connected to the reverse counting input of the first counter ( 13) and the data output of the linearizing circuit (14) is connected to the input of the display unit (15). The digital humidity meter according to claim 1, characterized in that the sensing unit (1) comprises a measuring cylinder (2), a capacitive measuring unit 13), a weighing unit (4) and a temperature measuring unit (5), 2) is arranged with its openable bottom above the capacitive measuring unit (3), the temperature measuring unit (5) is arranged inside the capacitive measuring unit (3) and the capacitive measuring unit (3) is mounted on the weighing unit (4), the measuring unit (3) is connected to the first input of the RC pulse generating circuit (6), the output of the temperature measuring unit (?) is connected to the second input of the pulse generating circuit fiC (o) and the weighing unit output (4) is connected to the input the amplification stage (10).