DE29908134U1 - Moisture indicator - Google Patents

Description

Description

Humidity indicator

The invention relates to a power-supplied device for determining and displaying the moisture content of solid, in particular porous, granular, earthy, grainy or dusty materials and substances.

In certain situations, it can be important to know or monitor the moisture status of various substances and materials so that they can be specifically influenced. For example, the growth of plants requires a certain level of moisture in the soil or in similar substrates with a porous or granular structure that are equivalent to soil. Certain materials, especially stored goods, must be protected from either spontaneous combustion or spoilage. In the home, the moisture in the root area of plants is determined, controlled and regulated mainly either by visual inspection of the soil, by floating water level indicators in plant boxes with water reservoirs or, in the case of a special, commercially available porous granulate as plant soil, by moisture indicators that work with a special fleece that changes color depending on the moisture level. In nurseries, in their greenhouses, in botanical institutes, in plant breeding chambers or in other agricultural or forestry facilities, but also in the area of storage, measuring devices that follow various measuring principles are used to measure, monitor and regulate the degree of humidity.

According to its product description for article number 642 03 5 D/A, 1999, the SERAMIS (R) watering indicator is an arrangement for displaying the moisture level of the SERAMIS (R) plant soil made of porous granulate in a dual type "damp-dry" and can only be used for the SERAMIS (R) plant soil. Even the size of the arrangement is limited to the specified plant pot dimensions, whereby this display arrangement must remain permanently inserted, otherwise the functional fleece would be destroyed and the failure to function would be inevitable. This moisture indicator, although simple, is therefore equipped with

suffers from significant defects, particularly in its extremely limited replaceability but also in relation to its possible functional failures when the device is moved and its limited usability.

DE OS 32 12 625 describes a device for testing or measuring the moisture content of materials and substances, in which two pin-shaped electrodes are arranged at a distance from one another. This electrode arrangement must be connected to a power source and to an electronic evaluation unit with a display element. The operation of this device is based on the fact that the electrical resistance of the moist or less moist material to be monitored, into which the electrodes are inserted, is measured. The same method is implemented by other published technical solutions, such as the procedure according to DE OS 32 01 474, whereby the main disadvantage of such measuring methods, including their arrangements, is recognized to be that such resistance or conductivity measurements in the substance or material to be examined are comparatively unreliable and inaccurate, since a whole series of influencing factors can falsify the measurement result. In particular, such measuring arrangements depend on the soil itself, which will usually be inhomogeneous. However, it is known that for acceptable measurement accuracy, the soil must be homogeneous, which is not possible in some cases. The conductivity of the material will also not always be proportional to its moisture content, as this conductivity also depends on fertilization measures and/or other conditions, as different electrolytes or electrolyte contents are encountered in the different measurements. In any case, two electrodes are always required.

DE OS 44 11 653 describes a measuring device for porous materials, in particular substrates in flower pots, which works with an electrode made of electrically conductive material that can be positioned on the outside of the measuring object. This measures capacitively and must be adapted on the side facing the measuring object to the curve of the measuring object section adjacent to it in the measuring position, which results in the considerable disadvantage of functional limitations and the complexity of the arrangement.

In particular, in the case of simple and uncomplicated measuring devices with dual statements "wet-dry" or with limit values and the associated automatic, informative signal outputs, there is still a considerable lack of reliability, particularly with regard to their power supply, measurement reliability and their universal replaceability.

Based on the causes and deficiencies of the humidity display devices belonging to the state of the art described above, the invention is based on the object of creating a device which avoids the aforementioned disadvantages, is miniaturized, easy and inexpensive to manufacture, simple and safe to handle and operate, and independent of external power suppliers with the generally usual connection and conversion or adaptation devices.

According to the invention, this task and objective is achieved by proposing a one-piece display device with the following construction.
The entire device is located in a tubular housing, preferably made of plastic, whose cross-section is round, oval, polygonal or otherwise designed according to the purpose and whose lower part tapers to a point where it accommodates a humidity sensor. The moisture exchange takes place through small openings in the housing around the humidity sensor, which is connected by cables to the other functional elements in the upper part of the housing. The other functional elements of the humidity indicator according to the invention are a solar cell, a charging circuit, a buffer battery, an evaluation electronics and an optical and/or acoustic signal generator. The solar cell located on the lower part of the device behind a transparent cover, hereinafter also referred to as a solar window, is connected to the charging circuit. This charging circuit is connected to the buffer battery, preferably a lithium secondary battery, which in turn, like the sensor, is connected to the evaluation electronics. The evaluation electronics operate the optical or acoustic signal generator.

The humidity sensor is mounted on the surface of an insulating ceramic substrate as two opposing, meandering resistance conductor tracks

At the end of each resistor conductor there is a trimming resistor to compensate for the switching behavior.
The solar/photovoltaic cell provided charges the buffer battery via an electronic charging circuit using the incident light, depending on its charge level. Depending on the light intensity, the device's circuitry is supplied by the solar cell or buffer battery depending on the current energy balance.

The measuring and switching electronics, also known as evaluation electronics, monitor and evaluate the moisture value of the material or substance to be monitored using an electrical state variable and, in accordance with a specification, a switching function is carried out for acoustic and/or optical signaling when the limit value is exceeded or not reached by the optical or acoustic signal generator(s). The circuit is designed for very low idle current consumption and low power consumption when the signal is emitted, so that the secondary/buffer battery is constantly charged in daylight or artificial lighting.

The invention is explained in more detail below using an exemplary embodiment.

Show it

Fig. 1: the block diagram of the humidity indicator,

Fig. 2: the components of the humidity indicator,
Fig. 3: the humidity sensor,

Fig. 4: the circuit arrangement of an advantageous embodiment with optical signal output,

Fig. 5: the circuit arrangement of an advantageous embodiment with acoustic signal emission.

In an advantageous embodiment of the invention, a tubular housing 1 made of plastic with a round cross-section, the lower part of which tapers to a point,

in this area a humidity sensor 2. The exchange of humidity can take place through small openings 12 in the housing 1 around the humidity sensor 2, whereby the humidity sensor 2 can develop its effect and measure the humidity formed in the microclimate. The humidity sensor 2 is connected to the other functional elements in the upper part of the housing by lines 3. A solar cell 4 is arranged on the upper part of the device behind a transparent cover in the housing 1 and is connected to the charging circuit 5. This charging circuit 5 is connected to a lithium secondary battery 6 as a buffer battery, which in turn, like the sensor 4, is connected to the evaluation electronics 7. The evaluation electronics 7 operate an optical signal generator 8 together with or alternatively to an acoustic signal generator.

The humidity sensor 2 is applied to the surface of insulating ceramic substrate 10 as two opposing, meandering resistance conductor tracks 11. These resistance conductor tracks 11 are designed in such a way that they change their electrical resistance when the moisture coming into contact with them changes. At the end of the resistance conductor tracks 11 there is a balancing resistor RX to compensate for the switching behavior.

The solar/photovoltaic cell 4 provided charges the buffer battery 6 via an electronic charging circuit 5 as a result of the incident light, depending on its charge level. Depending on the light intensity, the device's circuit arrangement is supplied depending on the current energy balance of the solar cell or buffer battery. The measuring and switching electronics 7, also referred to as evaluation electronics, monitors and evaluates the moisture value of the material or substance to be monitored, such as the soil of plants in greenhouses in garden centers or in flower pots in the home, using an electrical state variable. According to a specification, i.e. the specification of a limit value for the moisture content of the soil or a porous substance (plant granulate), a switching function is carried out for acoustic and/or optical signaling when the limit value is exceeded or not reached by the optical or acoustic signal generator 8. In the idle state, the power consumption is so low that the secondary battery 6 is constantly charged in daylight (intense, normal or diffuse to weak) or artificial lighting. Due to the low power requirement of the signal generator circuit, the

Battery provides a longer alarm. Due to the power supply via the solar cell 4 and the lithium secondary battery 6, the device is practically maintenance-free, provided that sufficient brightness cycles and a reaction to the signal are provided.

The electronic circuit 5 monitors and regulates the charge level of the battery. This special circuit arrangement enables very efficient use of the energy supplied by the solar cells. Due to the extremely low power consumption, the supply from solar cells and the long service life of the battery, the device is practically maintenance-free, which also ensures an effective contribution to environmental friendliness, especially with regard to the energy supply. The proposed humidity indicator has a very high level of reliability, is miniaturized, easy and inexpensive to manufacture, simple and safe to handle and operate, and independent of external power suppliers with the usually cumbersome connection and conversion or adaptation devices.

Claims (9)

&bgr; ·« Protection claims 1. Moisture indicator for determining and displaying the moisture of solid, in particular porous, granular, earthy, grainy to dusty materials and substances, characterized in that a moisture sensor (2) is arranged in a one-piece indicator with a tubular housing (1), the lower part of which tapers to a point, wherein small openings (12) are provided in the housing wall for the purpose of moisture exchange in the area of the moisture sensor (2), that a solar cell (4), a charging circuit (5), a buffer battery (6), an evaluation electronics (7) and a signal generator (8) are arranged in the upper part of the housing (1), and that the moisture sensor (2) is connected to the group of functional elements (4), (5), (6), (7), (8) arranged in the upper part of the housing (1) via a line (3). 2. Humidity indicator according to claim 1, characterized in that the tubular housing (1) has a round, oval, polygonal or other cross-section shaped according to the purpose. 3. Humidity indicator according to claim 1, characterized in that the tubular housing (1) is preferably made of plastic. 4. Humidity indicator according to claim 1, characterized in that a transparent or clear window (9) for the solar cell (4) is arranged on the upper part of the tubular housing (1). 5. Humidity indicator according to claim 1, characterized in that the humidity sensor (2) is applied to the surface of insulating ceramic substrate (10) as two opposing, meandering resistance conductor tracks (11) and that at the end of each of the resistance conductor tracks (11) there is a balancing resistor (RX) for the purpose of compensating the switching behavior. 6. Humidity indicator according to claim 1, characterized in that the signal generator (8) is provided as an optical and/or acoustic signal generator. 7. Moisture indicator for determining and displaying the moisture of solid, in particular porous, granular, earthy, grainy to dusty materials and substances, characterized in that a moisture sensor (2) in the form of resistance conductor tracks (11) with balancing resistor (RX) is connected to an evaluation or measuring electronic circuit (7), that one or more solar cells (4) are connected to a charging circuit (5), this charging circuit (5) in turn is connected to a buffer battery (6) and this circuit train (4), (5) and (6) in turn, like the sensor (2), is connected to the evaluation electronics (7), that the evaluation electronics (7) and the buffer battery (6) are connected to a signal generator (8). 8. Humidity indicator according to claim 7, characterized in that at the ends of the opposing, meandering resistance conductor tracks (11) balancing resistors (RX) are connected for the purpose of compensating the switching behavior. 9. Humidity indicator according to claim 7, characterized in that the circuit is designed for a very low quiescent current consumption, preferably for a quiescent current consumption in the range of approximately 0.5 to approximately 2 μA.