DE102016000659B4 - Device for indicating the earth moisture - Google Patents

Abstract

Device for indicating soil moisture, comprising a hollow body (10) which has at least one porous and water-permeable contact surface (11) to be brought into contact with the soil (1), wherein a cavity adjoining the contact surface can be filled with water and the water-saturated Contact surface (11) is gas-tight, wherein the cavity with at least one elastic element (13) is covered, which has at least a portion which is visibly deformed in the inserted into the soil device by means of a negative pressure in the interior of the hollow body (10) by the section with a continuous deformation under increasing negative pressure kinks or curves.

Description

The invention relates to a device for measuring and displaying the soil moisture in particular in planters for the interior by means of capillary force. Such measuring devices are known as Tensiometer.

They consist of an airtight, filled with water hollow body, which has a porous, permeable part at the bottom, which is gas-tight in the water-soaked state. This part of the tensiometer is put into the soil. The dry soil withdraws the hollow body via the capillaries of the porous part of water, it creates a suction stress, whereby a negative pressure is generated in the interior of the hollow body. Capillary forces in the soil draw the water to the ground against the negative pressure in the hollow body until equilibrium between the capillary forces and the negative pressure in the interior arises. If the dry soil is irrigated, the suction tension decreases and again water enters through the capillaries of the porous part into the hollow body, whereby the negative pressure decreases. The negative pressure inside the tensiometer is thus a measure of the soil moisture.

In the patent DE 39 11 151 A1 Such a tensiometer will be described. This is a conventional tensiometer in which the hollow body (measuring cell) is open at the top and only by the connection of a terminal device, in this case, an electrical pressure sensor, gas-tight is closed.

In the patent DE 10 2009 014 946 A1 a Tensiometer is described which has an additional sensor for measuring the moisture on the inner wall of the porous element on the porous part of the Tensiometers.

The known Tensiometerbauarten that measure the negative pressure by means of a mercury column, a mechanical pointer instrument or with an electronic pressure transducer are expensive by the use of expensive measuring instruments or include, as in the case of the mercury sen- sor, toxic components that do not allow use in the private sector.

The aim of the invention is therefore to provide a tensiometer with a display element that is very inexpensive and easy to read and allows a qualitative assessment of soil moisture. This makes it possible, for example, in indoor plants to provide each planter with its own Tensiometer. This ensures that the plants are sufficiently supplied with water.

The invention solves the problem by the fact that a visible part of the hollow body consists of a specially adapted to the task elastic part having a directly visible deformation under negative pressure. The degree of deformation can be interpreted as a measure of the drought in the soil. Thus, a deficiency of the plants with water can already be seen before the plant is damaged.

The capillary forces and thus the suction tension at the tensiometer depend on the water content of the soil. If there is no suction at the tensiometer, the soil is saturated, ie all pores are filled with water. On the other hand, if the suction tension at the tensiometer is high, this means that the plant must absorb water against this suction tension to cover its water requirement. When the so-called wilting point is reached, the capillary flow in the plant breaks off and it wilts. The optimal suction stress varies for each plant type and location condition. As a guideline for many plant species, the range between 150 and 250 mbar can be specified. At least 400 mbar should be irrigated. In the range of 0 to about 50 mbar, the earth is saturated, i. the pores are completely or mostly filled with water. In this state, the microorganisms lack oxygen and there are anaerobic conditions, which can lead to the formation of rot, which damages the plant. In the areas mentioned, the flexible part should have a degree of deformation which allows a conclusion to be too high or too low soil moisture.

The flexible part of the hollow body should be designed so that the deformation under vacuum is clearly visible. The extent of the deformation should be as linear as possible to the pressure drop in order to draw a conclusion about the current moisture content in the soil.

The claim of the plant to the soil moisture depends on its kind and on the site conditions. Therefore, it will be useful to perform different solid hollow body, which approximately take into account the water needs of each plant and the site conditions. Thus, a rather low stability of the elastic part of the hollow body would be suitable for high water requirement, so that a maximum deformation is reached even at 200 mbar vacuum. For a stiffer design with lower water requirements, the maximum deformation could be set at 400mbar vacuum.

The flexible part of the hollow body is removable. The lower part of the hollow body including the porous part is filled with water for startup. Then the flexible part will be back attached and the end with the porous part is inserted into the soil to be measured.

The interior of the elastic member does not necessarily have to be filled with water. However, the trapped air expands under vacuum, so that more water must penetrate the wall of the porous part in order to achieve a corresponding negative pressure in the hollow body than when fully filled without air entrapment. In the quantitative measuring tensiometers described above, such air pockets in the hollow body are avoided as far as possible. However, for a simple indication that only wants to make a qualitative assessment, air entrapment is only relevant in that the moisture content reading after irrigation takes a few minutes because the compressed volume of the air must be balanced by additional water passing through the porous part. The period of drying of the planter is already much longer anyway, so that here the duration of the volume compensation does not matter. If you want to avoid this air entrapment, so a closable filling can be attached to the top of the cavity, which allows the entire cavity to be completely filled with water.

The design of the elastic part must have the goal of achieving the greatest possible visible deformation. For example, in the simplest case, a piece of tubing may be used as the elastic member which is plugged onto an open socket on the hollow body and sealed on the other side with a plug or closure member which applies a weight force to the tubing. If now the negative pressure inside the device, the hose kinks inwards and loses its supporting effect for the closure element, so that this buckles down. In case of a sudden buckling, however, only one measuring point would be displayed. It is more advantageous to achieve a continuous deformation under increasing negative pressure. With a uniform deformation behavior, the user can qualitatively interpret the moisture content and relate it to the present planting situation.

An approach is therefore also a curved hollow body, similar to that used in manometers. In the arc, the convex surface is larger than the concave inner surface, so that contracts at a pressure difference between the interior of the hollow body and the outer atmospheric pressure of the arc.

In a further possible embodiment, the elastic part has different wall thicknesses at the front and back which at low pressure in the hollow body first dent the thinner wall and thereby the elastic part performs a movement in the direction of the thin wall. The variation of wall thicknesses and the introduction of reinforcements allows a variety of deformations of the elastic part can be achieved, including a twisting, which can also recognize clearly visible changes in shape under negative pressure with a suitable design of the element, such as lateral arms.

Another approach is the design analogous to a bellows that shortens under vacuum. If a tubular hollow body is provided only on one side with folds, which can contract, and the other side is pliable, but not shortened, this body will curve in the direction of the side with the bellows.

The elastic part of the hollow body must be made strong enough that the change in volume, which he experiences under negative pressure, is completely reversible. If this part were too thin-walled, it would have no power to draw the water back into the interior of the hollow body after irrigation from the soil through the porous part.

• 1 zeigt die Vorrichtung zur Anzeige der Erdfeuchte im Schnitt. Der poröse Teil (11) das Zwischenstück (12) und der flexible Teil (13) bilden zusammen den Hohlkörper (10), der im wasserbefüllten Zustand gasdicht ist. Durch Abnehmen des elastischen Elementes (13) kann diese Einheit bis zur Oberkante des Zwischenstücks (12) mit Wasser (2) gefüllt werden. Der poröse Teil (11) ist mit dem Zwischenstück dicht verbunden und befindet sich mit seiner Außenfläche im Kontakt mit dem Erdreich (1) dessen Feuchtigkeit ermittelt werden soll. Der poröse Teil ist als Kegel ausgeführt, damit er leicht in das Erdreich eingeführt werden kann. Das Zwischenstück (12) besteht vorzugsweise aus transparentem Material, so dass der Wasserstand im Inneren des Hohlkörpers sichtbar ist. Falls sich zu wenig Wasser im Hohlkörper befindet, ist somit eine Sichtkontrolle möglich und es kann gegebenenfalls Wasser nachgefüllt werden. Das elastische Element (13) ist als einseitiger Faltenbalg ausgeführt der sich bei Abnahme des Drucks im Inneren des Hohlkörpers zur gefalteten Seite neigt. Wenn bei einer Differenz des Kapillardrucks in Richtung des Erdreichs das Wasser durch das poröse Element in das trockene Erdreich gesaugt wird, verringert sich das Volumen im Hohlkörper (20) und das elastische Element verformt sich soweit, bis der Kapillardruck im Gleichgewicht mit dem inneren Unterdruck im Hohlkörper steht. Dieser innere Unterdruck wird durch die Rückstellkraft des elastischen Elementes gehalten. Wird das Erdreich bewässert, sinkt der Kapillardruck und durch die Rückstellkraft des elastischen Elementes wird Wasser aus dem Erdreich wieder ins Innere des Hohlkörpers gesaugt, wobei die Verformung des elastischen Elementes rückgängig gemacht wird.
• 2 zeigt die Vorrichtung zur Anzeige der Erdfeuchte mit einem elastischen Element (23) und einem Anzeigeelement (24). In dieser Anordnung ist nur das Anzeigeelement sichtbar und zeigt unmittelbar die Verformung des elastischen Elementes an. Der poröse Teil (21) das Zwischenstück (22) und der flexible Teil (23) und das Anzeigeelement (24) bilden zusammen den Hohlkörper (20), der im wassergefüllten Zustand gasdicht ist. Das Zwischenstück hat eine umlaufende Wandung, die den flexiblen Teil vom Erdreicht trennt. Diese Einheit ist mit Wasser (2) gefüllt. Der poröse Teil steht über seine Außenfläche im Kontakt mit dem Erdreich(1). Das Anzeigeelement (24) ist abnehmbar am oberen Ende des elastischen Elementes angebracht, wodurch der gesamte Hohlkörper mit Wasser gefüllt werden kann. Dadurch, dass nur wenig oder keine Luft sich im Inneren des Hohlkörpers befindet, verringert sich die Ansprechzeit der Anzeige, weil keine Volumenänderung der Luft durch Ausdehnung unter Unterdruck stattfindet. Dadurch tritt weniger Wasser durch das poröse Element bis die Kapillardruckdifferenz durch das elastische Element kompensiert wurde. Auch in dieser Ausführung ist das elastische Element als einseitiger Faltenbalg ausgeführt. Durch die Schwenkbewegung des Anzeigeelementes ist eine eindeutige Anzeige der Feuchteverhältnisse im Erdreich deutlich gegeben.
• Die 3 bis 5 zeigen die Vorrichtung zur Anzeige der Erdfeuchte nach der Ausführungsform wie in 1 in ihrem Verformungsverhalten. Der elastische Teil des Hohlkörpers ist so gestaltet, dass er im Ausgangszustand ohne inneren Unterdruck leicht nach hinten geneigt ist.
• 3 zeigt die Form des elastischen Elementes (13) im Zustand der Sättigung an. Sättigung heißt, dass das Erdreich vollständig mit Wasser getränkt ist und somit kein Kapillardruck herrscht. Der Hohlkörper ist somit drucklos. Der flexible Teil des Hohlkörpers (13) hat seine ursprüngliche Form behalten und signalisiert dem Benutzer eine zu hohe Erdfeuchte, weil durch die vollständige Durchtränkung der Erde Fäulnis auftreten kann
• 4 zeigt die Vorrichtung zur Anzeige der Erdfeuchte bei idealer Erdfeuchte. Durch eine leichte Verformung des elastischen Teils (13) wird angezeigt, dass ein leichter Unterdruck vorliegt, das Erdreich demnach nicht mit Wasser gesättigt ist, die Saugspannung aber noch deutlich unterhalb eines kritischen Bereiches ist.
• 5 zeigt die Vorrichtung zur Anzeige der Erdfeuchte in einem Zustand, bei dem das Erdreich bewässert werden sollte. Durch den Wasseraustritt hat sich ein größerer Unterdruck im Hohlkörper gebildet, durch das flexible Element (13) seine Form erheblich verändert hat, wodurch unzureichende Erdfeuchte anzeigt wird.

Two possible embodiments are explained in more detail below with reference to the drawings.

• 1 shows the device for displaying the soil moisture in section. The porous part ( 11 ) the intermediate piece ( 12 ) and the flexible part ( 13 ) together form the hollow body ( 10 ), which is gas-tight in the water-filled state. By removing the elastic element ( 13 ), this unit can reach the upper edge of the intermediate piece ( 12 ) with water ( 2 ) are filled. The porous part ( 11 ) is tightly connected to the intermediate piece and is located with its outer surface in contact with the soil ( 1 ) whose moisture is to be determined. The porous part is designed as a cone, so it can be easily introduced into the soil. The intermediate piece ( 12 ) is preferably made of transparent material, so that the water level in the interior of the hollow body is visible. If there is too little water in the hollow body, thus a visual inspection is possible and it can optionally be refilled water. The elastic element ( 13 ) is designed as a single-sided bellows tending to decrease the pressure in the interior of the hollow body to the folded side. If, in the case of a difference in the capillary pressure in the direction of the soil, the water is sucked through the porous element into the dry soil, the volume in the hollow body decreases ( 20 ) and the elastic element deforms until the capillary pressure is in equilibrium with the internal negative pressure in the hollow body. This internal negative pressure is held by the restoring force of the elastic element. If the soil is irrigated, the capillary pressure drops and the restoring force of the elastic element draws water from the soil back into the interior of the hollow body, reversing the deformation of the elastic element.
• 2 shows the device for indicating the soil moisture with an elastic element ( 23 ) and a display element ( 24 ). In this arrangement, only the display element is visible and directly indicates the deformation of the elastic element. The porous part ( 21 ) the intermediate piece ( 22 ) and the flexible part ( 23 ) and the display element ( 24 ) together form the hollow body ( 20 ), which is gas-tight in the water-filled state. The intermediate piece has a circumferential wall which separates the flexible part from the earth. This unit is filled with water ( 2 ) filled. The porous part is in contact with the soil via its outer surface ( 1 ). The display element ( 24 ) is removably attached to the upper end of the elastic member, whereby the entire hollow body can be filled with water. The fact that there is little or no air in the interior of the hollow body, the response of the display is reduced because no change in volume of the air takes place by expansion under negative pressure. As a result, less water passes through the porous element until the capillary pressure difference has been compensated by the elastic element. Also in this embodiment, the elastic element is designed as a one-sided bellows. Due to the pivoting movement of the display element a clear indication of the moisture conditions in the soil is given clearly.
• The 3 to 5 show the device for indicating the soil moisture according to the embodiment as in 1 in their deformation behavior. The elastic part of the hollow body is designed so that it is slightly inclined in the initial state without internal negative pressure to the rear.
• 3 shows the shape of the elastic element ( 13 ) in the state of saturation. Saturation means that the soil is completely saturated with water and thus there is no capillary pressure. The hollow body is thus pressureless. The flexible part of the hollow body ( 13 ) has retained its original shape and signals the user too high soil moisture, because through the complete saturation of the soil rot can occur
• 4 shows the device for the display of soil moisture at ideal soil moisture. By a slight deformation of the elastic part ( 13 ) indicates that there is a slight negative pressure, the soil is therefore not saturated with water, but the suction voltage is still well below a critical range.
• 5 shows the device for indicating the soil moisture in a state in which the soil should be watered. By the water outlet, a larger negative pressure in the hollow body has formed, by the flexible element ( 13 ) has changed its shape significantly, indicating insufficient soil moisture.

Claims (8)

Device for indicating soil moisture, comprising a hollow body (10) which has at least one porous and water-permeable contact surface (11) to be brought into contact with the soil (1), wherein a cavity adjoining the contact surface can be filled with water and the water-saturated Contact surface (11) is gas-tight, wherein the cavity with at least one elastic element (13) is covered, which has at least a portion which is visibly deformed in the inserted into the soil device by means of a negative pressure in the interior of the hollow body (10) by the section with a continuous deformation under increasing negative pressure kinks or curves. Device for displaying soil moisture after Claim 1 , characterized in that the elastic portion is designed as a one-sided stiffened bellows. Device according to one of Claims 1 to 2 , characterized in that the elasticity of the elastic portion of the hollow body (10) is adjusted by varying the wall thickness. Device according to one of Claims 1 to 3 , characterized in that the wall thicknesses of the elastic portion of the hollow body (10) on the front and back are different. Device according to one of Claims 1 to 4 , characterized in that the elastic portion of the hollow body (10) is performed in different strengths. Device according to one of Claims 1 to 5 , characterized in that at the upper end of the elastic element (13) is an airtight sealable filling opening. Device for displaying the soil moisture according to one of Claims 1 to 6 , characterized in that the elastic element of the hollow body (10) consists of natural latex. Device for displaying the soil moisture after the Claim 1 , characterized in that the elastic portion has the shape of an arc.

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