DE19710591A1 - Method for contactless moisture content measurement, used in agriculture - Google Patents

Abstract

The method involves using two resonant circuits arranged close to the object to be measured. The inductive coupling of the two circuits is amplified to measure the high moisture level of the object material. The material is stimulated by a high frequency electromagnetic alternating field generated by one tuned resonant circuit. The other resonant circuit arranged on the other side of the material is connected to a measurement receiver.

Description

1. State of the art and problem

When growing plants outdoors - e.g. B. at an Eriken culture or in nurseries - all plants become the same, i.e. regardless of their actual need by means of a Irrigated watering car.

However, a plant population has never dried out evenly. The irrigation must target the driest plants. As a result, a very large proportion of the No irrigation water existed at the moment of irrigation needed. In most of the plants, the irrigation water flows with the fertilizer dissolved in it therefore through the pots into the surrounding soil, which is significant cost, as well causes a pollution of the environment.

To solve the problem of unsatisfactory irrigation, a system would be required which measures the actual soil moisture of each individual plant and converts it into one plant-specific irrigation (up to 300,000 plants per field). The technical Difficulties lie in particular in the contactless detection of the Soil moisture of the respective plant pot. Irrigation can be done easily computer controlled solenoid valves.

The measuring method must meet the following requirements:

• - non-contact and non-destructive measurement,
• - measuring range between F _M = 60-85% by weight of water,
• - Objects with a diameter of approx. 10-15 cm must be able to be detected,
• - Position deviations of the measurement object up to approx. ΔS = 5 cm must not influence the Take measurement result,
• - the measuring and irrigation system must be very simple (costs),
• - The EMC regulations (electromagnetic compatibility) must be without an additional Shielding of the sensors are observed. (Shielding would be too expensive),
• - The measurement result must not be caused by changes in the surrounding soil (e.g. Puddles of water) or are influenced by thin water films on the test objects,
• - low maintenance, d. H. no mechanical wear parts (e.g. touching the Pot by passing electrodes),
• - The plant substrate is covered by the pot and the plant, d. H. optical processes (IR absorption method) are out of the question.

As part of a research project / 1 / an attempt was made to develop such a system. It was found that none of the material moisture measurement methods described in the literature are suitable for solving this problem at a reasonable cost. (In the nearby microwave transmission or reflection method, the waves are almost completely absorbed or reflected even at a material moisture content of F _M = 60% by weight, which makes a measurement in the mentioned range impossible).

This problem therefore led to the development of what is described below Material moisture measurement method.  

2. Description of the measurement procedure

In the newly developed measuring method, the change in the inductive coupling of two resonant circuits is used for moisture determination. The test object is excited by means of a high-frequency, alternating electromagnetic field, which is generated by a coordinated resonant circuit. Figure 1 shows the circuit principle, the mechanical arrangement is shown in Figure 2. On the opposite side of the test object there is a second resonant circuit, tuned to the same resonance frequency, which is connected to a test receiver.

In order to suppress capacitive effects, the coils are grounded in the middle, so that the partially compensate for electrical fields. (The capacitive coupling increases especially with smaller objects with low material moisture). Therefore must HF-grounding of the coil must also be carried out with particular care, in particular by Standing shifts due to standing waves are to be avoided (e.g. through use coordinated supply lines).

The coils of the two resonant circuits are arranged in such a way that an imaginary axis, which leads through the center of the test object, is wrapped by the individual turns (see Figure 2). With increasing material moisture of the measurement object, the inductive coupling of the two resonant circuits improves, so that the amplitude in the received resonant circuit increases. In contrast to the microwave absorption process, the field strength in the receiver is high with high material moisture (low damping) and low with low water content (high damping).

The increase in field strength can be explained by adding the following physical effects:

• - Due to the increasing electrical conductivity with increasing humidity arise in Measurement object eddy currents.
• - Due to the high dielectric constant (ε _{r water} ≈ 80) and the resulting shortened wavelength (at 433 MHz: λ _water ≈ 8.3 cm), standing and progressing electromagnetic waves can propagate in the test object. (The deprivation of energy due to the vibrations of the water molecules is of minor importance if the measuring frequency is low and the object is thin.)

Figure 3 shows the field strength as a function of the material moisture (characteristic curve). A plant pot filled with d = 10 cm and filled with white peat was chosen as the test object. The distance between the transmitting and receiving antennas is approx. S = 14 cm. The RF signal was rectified linearly at the receiver. By changing the transmission power or the sensitivity of the receiver, the steep part of the characteristic curve can be shifted in the range of approx. F _m = 50-80% by weight. If a logarithmic measuring receiver is used (display in dB instead of in mV), the measuring range can be expanded to approx. 40-85% by weight of water. Due to the steep slope of the characteristic curve, despite its simple structure, it is insensitive to interference.

The characteristic is strongly dependent on the quality of the resonant circuit and the size of the air gap between the coils and the object to be measured. Positional deviations of the measurement object as well Metal objects or the like directly next to the measurement object have only an insignificant one Germ line shift if the distance between the transmitting and receiving coil is not changed. However, there must be a minimum distance between the test object and the coil of approx. d = 5 mm, so that the resonance frequency and the quality of the Resonant circuit not through a capacitive coupling between the coil and the test object being affected. Also a thin film of water (e.g. damp outer walls of the test object) affects the measurement result only marginally.

Depending on the size of the object and the desired measuring range, the measuring frequency should be approx. F _m = 100-1000 MHz. The frequency f _m = 433.92 MHz approved for industrial purposes is therefore particularly suitable for the application area described. In order to achieve high sensitivity, the quality of the two resonant circuits should be as high as possible. (If the transmission power or receiver sensitivity is increased, the disruptive capacitive effects also increase).

The transmitting and receiving coils can also be located on the same side of the test object, provided that a direct coupling between the two coils is prevented by sufficient distance and, if necessary, shielding ( Figure 4). Here, however, a change in the distance between the object to be measured and the coils has a significant effect on the measurement result.

3. Examples of use 3.1 Plant-specific irrigation using a watering car

Figure 5 shows the structure of a complete soil moisture measurement and watering system for plant-specific irrigation and fertilization using a watering car.

The transmit and receive antennas attached to the watering car are located between the individual rows of plants. There are 2 resonant circuits in a housing that are coupled to a common transmitter or receiver. The measuring antennas therefore have a bidirectional characteristic, ie they radiate both to the left and to the right. With a combination of transmitting and receiving antennas, two top rows are covered. The transmission antennas are supplied with commercially available oscillator modules (e.g. measuring frequency: f _m = 433.92 Mhz, output power Pout = 20 mW). In the receiver modules, the strength of the signals is converted into direct voltages proportional to the field strength and fed to a process computer via a multiplexer. In order to determine the moisture of the row of plants standing to the left or right of the receiver, the corresponding transmitter group is released by the computer.

The signals are evaluated, the casting time is calculated and the time sequence is controlled also with the help of the process computer.

The irrigation takes place during the continuous movement of the casting car Solenoid valves. The determination of the position for the measuring and for the casting process can either by a light barrier or by a software evaluation of the Signal changes of the receiver modules take place.

2. Leakage detection on sewers

Older sewage pipes often show damage and leaks. The sewage leaks at the leaks and pollutes the environment. This damage will be usually localized and examined using a small television camera. This can only the internal condition of the channel can be checked. However, whether wastewater can actually escape can often not be determined by this so-called TV driving. So there are none precise statements about the endangerment of soil and groundwater possible / 2 /. There one Rehabilitation of the sewer is associated with very high costs, additional would be here Information about the amount of water leaking is desirable.

By mounting the measuring arrangement shown in Figure 4 on a sewer probe, a significant increase in soil moisture below the sewer pipe can be localized ( Figure 6). The thin water film at the bottom of the sewer pipe has only an insignificant effect on the measurement result.

In combination with the television investigation, statements about the amount of actually emerging waste water possible.  

4. Bibliography

/ 1 / Eissler, W .; Among other things, automatic soil moisture measurement and irrigation water metering in the greenhouse and in the field of growing plants.
Final report of the joint research project, funded by the Ministry for Rural Affairs, Food, Agriculture and Forestry, Baden-Württemberg, Az: 24-8251.32.
Steinbeis transfer center for sensors and systems, Reutlingen, 1993.
/ 2 / EISWIRTH, M .; Among other things, new methods of leak detection in sewers. gwf-water-wastewater, 135 (6): 312-318, 1994.

Claims (1)

Method and device for the contactless measurement of the material moisture in the high humidity range, characterized in that the amplification of the inductive coupling of two resonant circuits located next to the measurement object is used to measure the moisture at high material moisture.