DE10245411B3 - Moisture sensor for determining moisture from leakages in reservoir, clarifying tanks and swimming pools comprises measuring line sections, screened by-pass lines, a switch, and control lines for controlling the switch - Google Patents

Abstract

Moisture sensor comprises several measuring line sections (1) forming the measuring line, screened by-pass lines running parallel to the measuring line sections, a switch (3) between the single measuring line sections and the by-pass lines for selecting single measuring line sections, and control lines (5) for controlling the switch.

Description

The invention relates to a moisture sensor measuring lines arranged in sections for spatially resolved water content determination according to claim 1.

For In many applications it is important to have water content and its distribution to determine in a material. So can by a spatially resolved moisture determination early Leaks in structures such as dams, clarifiers, Landfill seals, structures in groundwater or swimming pools be recognized. this makes possible a small-scale, favorable Repair of damaged areas. At the same time it becomes significant Consequential damage through prevents undetected leaks.

In agriculture and gardening depends on the optimal irrigation from the large-scale but spatially resolved measurement the soil moisture. A low water supply leads to damage to the plants, while a over irrigation washing out the nutrients and caused salinization. Even heavily used green spaces like on golf courses or need in sports stadiums targeted irrigation dependent on the soil moisture distribution.

Biofilters are increasingly used for cleaning of exhaust gases. Their effect depends heavily on the water content which has a very large local variability in the biofilter. With a spatially resolved These differences in water content can be determined by measuring moisture and an irrigation system regulate specifically. This ensures that the biofilter remains functional and reduces the environmental impact. In addition, smaller, cost-effective Filter systems with the same effect as unregulated systems are used.

It always happens in the construction sector for moisturizing insulation constructions such as. for flat roofs. An early spatially resolved moisture determination allows the cost-effective here too small-scale Repair. About that in addition one achieves a saving of heating energy which otherwise with dampened but not yet recognized as faulty insulation must become.

Leakage on pipes, e.g. for water and district heating supply should also be recognized and reported in a location-resolved manner. Let it through carry out repairs faster and the consequential damage e.g. by minimizing supply interruptions.

Usually used for moisture determination Probes used, the dielectric coefficient DK of the to be examined Measure material. Leaves it determine the humidity with the help of calibration measurements. On introduced The method is the time domain reflection measurement or Engl. Time Domain reflectometry (TDR) called. It is based on the spread electromagnetic waves along lines. The electrical Properties of cables and thus signal transmission are among others by the characteristic impedance, the damping and the speed of propagation are described. These sizes are known to depend on the lossy dielectric of the room, via which the electric field extends. This space is at coaxial Wires through the outer shield limited. In open line systems such as the double line (Lecher line) or three and multiple lines, however, the field penetrates through the next Around the ladder. A change in the material properties there how the water content changes the above transmission properties.

The time domain reflectometry (TDR) for water content measurement in soils is known, for example, from the magazine Wasser + Boden (R. Rook, S. Melchior, G. Miehlich, "The Time Domain Reflectometry (TDR) for water content measurement in soils", Wasser + No. 4, 1993) The typical probes presented there have a measuring fork designed as an open line with a very short measuring distance. In general, TDR probes are only manufactured and offered in lengths of a few 10 centimeters. German Patent No. 19 501 196 states described a moisture sensor for extended layers, which allows much longer cable lengths and enables spatial resolution with the help of crosstalk at cable crossings.This sensor is mainly suitable for areal measurement tasks with simple geometry.A resolution along linear structures such as pipes is not feasible Sensor depends on the number of possible crosstalk units and is t thereby clearly limited. An increase in the spatial resolution is only possible by increasing the number of test leads, which leads to high costs and installation effort. Hook et al. (Hook, WR, Livingston, NJ, Sun, ZJ and PB Hook, "Remote Diode Shorting Improves Measurement of Soil Water by Time Domain Reflectometry", Soil Sci. Soc. Am. J., No. 56, 1383-1391, 1992) describe a moisture sensor, which consists of strings of lines that can be separated from each other by short-circuit diodes. It can be used to distinguish between several sections along a measuring line. However, the maximum length of the sensor is limited to a few meters. A disadvantageous effect is that the fed-in signal for measuring a section has to go through all the measuring sections lying in front of it and is thereby strongly attenuated. In addition, the multiple reflections that occur complicate the evaluation of the signals (see Sun, ZJ and GD Young, 2001, “A cost effective soil moisture Instru ment based on time domain transmission measurement ", Proceedings of the Second International Symposium and Workshop on Time Domain Reflectometry for Innovative Geotechnical Applications, Evanston, September 5–7, 109-115). Another approach to spatial resolution along a measurement section is described by Schlaeger et al. (Schlaeger, S, Huebner, C., Scheuermann, A. and J. Gottlieb, 2001, "Development and application of TDR inversion algorithms with high spatial resolution for moisture profile determination", Proceedings of the Second International Symposium and Workshop on Time Domain Reflectometry for Innovative Geotechnical Applications, Evanston, September 5-7, 236-248). The reflected signals are evaluated by a complex mathematical algorithm and the moisture profile along the measuring line is determined. The possible measuring length is also limited here due to the inevitable damping and dispersion of the material over short distances.

The object of the invention is To design the sensor so that it has the largest possible and arbitrarily shaped surface or a route with high spatial resolution detected. Solved is achieved by the features of claim 1.

The subclaims describe advantageous configurations of the sensor.

The invention is illustrated below an example explained with the help of the figures.

The shows 1 the schematic structure of part of the measuring line and the 2 the diagram of a complete measuring arrangement.

The 1 shows a section of the moisture sensor. A section of the moisture sensor consists of a measuring line 1 , a bypass 2 and a control line 5 , The individual sections are via shielded connecting cables 4 connected in series with each other. The connecting lines can be omitted if the sections are to follow one after the other. The test leads 1 preferably consist of multi-core open cables. Three-core ribbon cables are advantageous, the two outer conductors of which are connected to ground. This achieves favorable damping properties and a good adaptation to the coaxial cables of the bypass and connecting lines 2 . 4 , At the same time, these ribbon cables prove to be mechanically stable, within certain limits they can follow settling in the material and they are easy to lay and assemble. Incompletely shielded coaxial cables (so-called leaking coaxial cables) can also be used as the measuring line. The spreading properties of these coaxial cables are therefore influenced by the water content. Lines as described in German Patent No. 198 33 331 “Moisture Sensor for Layers” are also suitable.

The bypass and the connecting lines 2 . 4 are designed as low-loss coaxial cables. Mechanical and / or electronic switches are located between the sections or between sections and connecting lines 3 arranged that a switchover between bypass and measuring line 2 . 1 enable. The switches 3 are about control lines 5 provided. The control lines can be omitted if the switches at the connection points have a suitable decoding device, which is controlled via the measuring line and the bypasses 1 . 2 allows. The moisture sensor can optionally be operated with one of three measuring methods, which differ in terms of accuracy, cost and type of installation.

measurement methods 1 uses a time domain reflectometer. The section to be measured is selected via a control circuit. The lines in front of this section are switched to bypass by the switches. The switch immediately after the section is placed on the bypass so that the measuring line has an open end. There is a reflection of the pulse emitted by the time domain reflectometer. From the transit time of the pulse minus the transit time of the bypass and connection cables in front of it, the dielectric coefficient along the measuring line and the water content can be determined. To increase the accuracy, the measurement process can be preceded by a reference measurement. To do this, put the switch in front of the section to be measured on bypass and the switch after the section on the measuring line. There is a reflection at the open end of the bypass. The runtime determined from this can be offset against the runtime of the actual measurement and enables the compensation of temperature-dependent changes in length of the bypasses and connecting lines. One advantage of this measuring method is that the end of the moisture sensor does not have to be returned to the measuring device. This is beneficial for measurements along routes, such as when monitoring pipelines. It is disadvantageous that the pulse rise time increases significantly with increasing cable length and thus the time resolution and thus the accuracy of the measurement decrease.

measurement methods 2 uses a time domain meter for transmission measurements. The section to be measured is selected via a control circuit. The routes before and after are switched to bypass. A fed impulse runs through the bypasses in front of the section, through the measuring line and then through the bypasses behind the section. The total term of the Im pulses minus the transit times through the bypasses and connecting lines is a measure of the dielectric coefficient along the measuring line or the water content. To increase the accuracy, the measurement process can be preceded by a reference measurement. To do this, put all switches on bypass. The runtime determined in this configuration can be offset against the runtime of the actual measurement and enables compensation for temperature-dependent changes in length of the bypasses and connecting lines. One advantage of this measuring method is the cost-effective implementation of the transit time measurement in transmission using commercially available components. It is disadvantageous that the pulse rise time increases significantly with increasing cable length and thus the time resolution and thus the accuracy of the measurement decrease.

measurement methods 3 uses an amplitude / phase meter for transmission measurements. The section to be measured is selected via a control circuit. The routes before and after are switched to bypass. The fed signals experience an attenuation and a phase shift. The phase shift minus the phase shift through the bypasses and connecting lines is a measure of the dielectric coefficient along the measuring line or the water content. To increase the accuracy, the measurement process can be preceded by a reference measurement. To do this, put all switches on bypass. The phase rotation determined in this configuration can be offset against the phase rotation of the actual measurement and enables compensation for temperature-dependent changes in length of the bypasses and connecting lines. This measurement method is more precise than the measurement method 1 and 2 , However, the prerequisite is that the attenuation of the test leads is sufficiently high to suppress multiple reflections (approx. 10 dB attenuation are sufficient). With a damping measurement, a favorable frequency range is determined in which the measurement takes place. Even greater accuracy can be achieved if the phase rotation is determined from several frequencies over this frequency and forms the mean phase steepness, which in turn can be related to the water content, for example, by calibration.

2 shows a possible installation arrangement of the moisture sensor together with a control unit 6 , Typical implementations are, for example, sensors with a length of 100 m which contain 20 sections of 5 m each.

Claims (7)

Moisture sensor consisting of a multi-core measuring line and a phase / amplitude measuring device or a time domain measuring device, characterized by a) several multi-core measuring line sections ( 1 ) that form the measuring line, b) shielded bypass lines running parallel to the measuring line sections ( 2 ), c) switch ( 3 ) between the individual test lead sections ( 1 ) and the bypass lines running in parallel ( 2 ) to select individual test lead sections ( 1 ), whereby instead of unselected test lead sections ( 1 ) the corresponding bypass lines ( 2 ) are activated and d) means ( 5 ) to control the switches ( 3 ). Humidity sensor according to claim 1, characterized in that between the individual measuring line sections ( 1 ) shielded cables ( 4 ) are arranged for connection. Moisture sensor according to one of claims 1 to 2, characterized in that the measuring line sections ( 1 ) consist of three conductors, two conductors having a common shield. Moisture sensor according to one of claims 1 to 2, characterized in that the measuring line sections ( 1 ) are not fully shielded coaxial cables. Moisture sensor according to one of claims 1 to 2, characterized in that the means ( 5 ) to control the. Switches are control cables and supply cables. Moisture sensor according to one of the claims 1 to 2 , characterized in that the means ( 5 ) to control the switches ( 3) Decoding circuits that are connected via the measuring and bypass lines ( 1 . 2 ) be addressed. Moisture sensor according to one of claims 1 to 6, characterized in that the damping of the respectively active Test lead sections is at least 10 dB.