WO2024022595A1 - Soil moisture apparatus for plants - Google Patents

Abstract

The invention relates to a soil moisture apparatus for plants, having a housing for accommodating the plants and having a moisture measuring device containing a first capacitor electrode and a second capacitor electrode and an evaluation device, wherein the housing is of multi-part design and contains an inner pot for accommodating the plant soil and a cover pot that surrounds the inner pot on a base wall thereof and/or on a side wall thereof that rises from the base wall, or an inner pot for accommodating the plant soil and an intermediate pot that surrounds the inner pot on a base wall thereof and/or on a side wall thereof, and a cover pot that surrounds the intermediate pot on a base wall thereof and on a side wall thereof, and the first capacitor electrode and the second capacitor electrode are arranged on an inside of a base wall and/or of a side wall of the cover pot and/or of the intermediate pot, which inside faces the inner pot.

Description

Soil moisture device for plants

The invention relates to a soil moisture device for plants according to the preamble of claim 1.

From EP 3 145292 B1 a moisture measuring device for plants is known, which comprises an evaluation device and two capacitor electrodes. The capacitor electrodes are inserted into plant soil in the plant pot.

From DE 10 2020 118 565 A1 a moisture measuring device for plants is known which has capacitor electrodes arranged at a distance from one another. These are inserted into the soil of a plant pot. The disadvantage of the known measuring device is that it is a hindrance when watering the plant pot or its position is changed in an undesirable manner.

From DE 20 2016 005 957 U1 Uhr is a soil moisture measuring device for plants with a housing for holding plant soil and with a Moisture measuring device containing a first capacitor electrode and a second capacitor electrode and an evaluation device are known. The capacitor electrodes and the evaluation device are arranged in a bottom area of the housing. The disadvantage of this is that the volume requirement is relatively large.

The object of the present invention is therefore to develop a soil moisture device in such a way that comfort and usability are improved.

To solve this problem, the invention has the features of patent claim 1.

The particular advantage of the invention is that the multi-part design of a housing to accommodate the plant creates a physical separation between the actual plant or plant soil on the one hand and the moisture measuring device on the other. The plant is planted in potting soil surrounded by an inner pot. The two capacitor electrodes are arranged on the outside of a planter or an intermediate pot surrounding the inner pot. In terms of handling, the commercially available inner pot containing the plant and the plant soil can be inserted into the planter or intermediate pot without the need for additional fastening of parts of the moisture measuring device.

According to a preferred embodiment of the invention, a first capacitor electrode and/or a second capacitor electrode is formed over a large area, specifically along a circumferential angle of at least 40°, preferably in a range of 160° to 175°. The circumferential angle extends around an axis of symmetry of the planter or inner pot. Preferably, the electrodes each extend from a base path to an upper opening edge of the planter or intermediate pot. Preferably, the first capacitor electrode and the second capacitor electrode extend over an area of the same size. Advantageously, a good measurement result can be achieved without the user of the plant being hindered in the treatment (watering) of the plant.

According to a further development of the invention, the first capacitor electrode and the second capacitor electrode are each designed as an electrically conductive film, which are materially connected to an outside of the planter or the intermediate pot. The electrodes and the supply lines are advantageously arranged in a space-saving manner and are protected from contact/impairment by the wall of the planter or intermediate pot.

According to a further development of the invention, the planter is designed in two parts with a first part and a second part surrounded by the first part. The first part has the capacitor electrodes and is preferably arranged in an upper section of the second part. A chamber for accommodating the evaluation device is provided in a lower section of the first part. The first part thus surrounds the second part, with both parts preferably ending flush at an upper opening edge. The first part is designed in such a way that the evaluation device is attached to an upper edge of the first part. a second part could be designed so that the evaluation device fits directly at the top edge.

According to a further development of the invention, the part of the planter has opposite grooves on the inside which run in a vertical direction. The grooves are free of electrodes or limit the edges of the capacitor electrodes. The grooves thus advantageously define the arrangement of the electrodes on the outside of the first part. According to a further development of the invention, electrical cables which can be connected to connections of the evaluation device protrude from an intermediate pot which has the first capacitor electrode and the second capacitor electrode on the inside or outside or inside. The intermediate pot serves exclusively as a support for the first capacitor electrode, for the second capacitor electrode and for the connecting cables of the electrodes. The planter is used to accommodate the evaluation device and to accommodate the intermediate pot, with an inside of the planter resting flat against an outside of the intermediate pot. The intermediate pot is used to accommodate the inner pot that supports the plant.

According to a further development of the invention, the evaluation device has a solar panel and/or a supercapacitor, by means of which the electrical supply to the evaluation device is guaranteed. This can advantageously save energy.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawings.

Show it:

1 A schematic representation of a soil moisture device according to a first embodiment, wherein a planter of the soil moisture device is designed in two parts,

2 is a perspective view of an inner second part of the planter according to FIG. 1,

3 is a top view of the second part according to FIG. 2, 4 shows a representation of a one-piece planter according to a further embodiment of the invention,

Fig. 5 is a side view of a one-piece planter according to a further embodiment of the invention and

6 is a perspective view of an intermediate pot according to the invention.

A soil moisture device for plants has a housing for holding the plant 25 and a plant soil 24 as well as a moisture measuring device 1.

According to the invention, the housing is designed in several parts, having a planter 2 on the one hand and an inner pot 3 on the other. The inner pot 3 is used to hold the plant soil 24 and the plant 25.

The planter 2 according to the embodiment according to Figures 1 to 3 is designed in two parts and has a first part 4 and a second part 5 surrounded by the first part 4. The inner pot 3 can be a commercially available planter made of stoneware or plastic or the like of any design. The first part 4 has a bottom wall 6 and a side wall 7 extending upright from it. The side wall 7 can be cylindrical or frustoconical

The second part 5 is - like the first part 4 - pot-shaped with a bottom wall 8 and an upright side wall 9. The second part 5 is designed in such a way that it can be inserted into the first part 4 with play.

The second part 5 is in one on one of the bottom walls 6 of the first

Part 4 arranged upper section 10 of the first part 4 arranged. In a lower section 11 of the first part 4 facing the bottom wall 6, a chamber 12 is arranged, in which an evaluation device 13 of the moisture measuring device 1 is arranged. The evaluation device 13 includes electronics 13 'with a microprocessor and a program for programming a determination of the watering requirement and / or for automatic watering of the inner pot 3. For example, the evaluation device 13 can generate a signal when the moisture content of the monitored plant soil 24 is at a critical threshold drops. To measure the moisture of the plant soil 24, the evaluation device 13 has a first capacitor electrode 14 and a second capacitor electrode 15, which are arranged integrated in the second part 5 of the planter 2. The two electrons 14, 15 are connected to the evaluation device 13 via supply lines (not shown).

A solar panel 16 and/or a supercapacitor 17 is provided to power the evaluation device 13. The solar panel 16 is arranged outside the planter, for example next to it, and can, for example, charge the supercapacitor 17. Alternatively, the solar panel 16 is located inside the planter 2 or the first part 4. If the first part 4 is cuboid and / or polygonal, a rigid solar panel 16 is arranged on an outside of the first part 4. If the first part 4 is curved, a flexible solar panel 16 is arranged flat on an outside of the first part 4.

For example, the evaluation device 13 can have an evaluation program so that the moisture content of the plant soil 24 is measured once per day. This moisture value is stored in a memory of the evaluation device 13 until the next measurement. The evaluation device 13 is connected to an optical signaling device 18, which can, for example, have an LED light source to signal a dry state of the plant soil 24. The moisture content decreases For example, below the threshold value, the color of the light source changes from, for example, the color green to the color red. Alternatively, the light source can also be designed in one color. The dry state of the plant soil 24 can then be shown, for example, by a lighting frequency of the light source. The user is thus signaled that he must add liquid to the plant soil 24.

Furthermore, the evaluation device 13 can be connected to a radio module 19, so that the drying status can be transmitted to a mobile data device, for example via WLAN.

To supply water and meter the plant soil 24 with water, the evaluation device 13 is connected to a switching element 20, for example an electric valve or a pump for conveying water from an external water resource reservoir to the plant soil 24 in the inner pot 3.

Furthermore, the evaluation device 13 can have separating resistors and/or inductors 21, so that signals can be provided for test purposes and at the same time the disruptive effect of the measuring lines used is minimized.

As can be seen from Figure 2, the first capacitor electrode 14 and the second capacitor electrode 15 are arranged on an outside of the second part 5 of the planter 2. The first capacitor electrode 14 and the second capacitor electrode 15 are designed to have a large area and preferably have the same dimension . The first capacitor electrode 14 and the second capacitor electrode 15 are arranged opposite one another on the outside of the side wall 9 of the second part 5. They are each only separated from one another by an upright groove 22, the groove 22 extending on the inside of the side wall 9 from the bottom wall 8 to a free opening edge 23 of the inner part 5. The first capacitor electrode 14 and the second capacitor electrode 15 each extend at a circumferential angle φ of at least 40°, preferably in a range of 160° to 174°. In the present exemplary embodiment, the first capacitor electrode 14 and the second capacitor electrode 15 each extend along a circumferential angle φ of 175°. The circumferential angle φ extends in the circumferential direction U around an axis A of the second part 5. If the second part 5 is cylindrical, the first capacitor electrode 14 and the second capacitor electrode 15 are partially cylindrical. With respect to a central plane M of the second part 5, the first capacitor electrode 14 and the second capacitor electrode 15 run symmetrically to one another.

The first capacitor electrode 14 and the second capacitor electrode 15 are each designed as an electrically conductive foil, for example aluminum foil. They are cohesively connected to the outside of the second part 5, for example by adhesive (self-adhesive film). Alternatively, the capacitor electrodes 14, 15 can be formed by applying electrically conductive materials, for example paints.

The inner pot 3, which contains the plant soil 24 and the plant 25, preferably consists of a plastic material with a bottom wall 26 and a side wall 27 running upright from it. The base wall 26 usually has perforations, so that moisture or .Water can be supplied, for example for orchids.

The second part 5 of the planter 2 is designed in such a way that the inner pot 3 can be inserted into it with play. According to a further embodiment of the invention according to FIG. 4, a one-piece planter 2' is provided, in which only a first capacitor electrode 14' is arranged on the outside of the planter 2'. A second capacitor electrode 15' protrudes from a bottom wall 8' of the planter 2', and is preferably located in a sleeve that is integrally connected to the planter 2'. The first capacitor electrode 14' extends at a circumferential angle φ in a range between 272° and 355°. The first capacitor electrode 14' is only interrupted by a groove 22*.

Alternatively, the component according to FIG. 4 can also be an alternative second part 4 of the planter 2 according to FIG. 1.

According to a further embodiment of the invention according to Figure 5, a planter 2" is formed in one piece, with the first capacitor electrode 14' being arranged on an outside of the side wall 28 and the second capacitor electrode 15' rising from a bottom wall 29. The planter 2" corresponds essentially the planter 2* according to FIG. 4, whereby in contrast to this a side web 30 protrudes from the side wall 28 for fastening the planter 2" to a vertical wall.

According to a further embodiment of the invention according to Figure 6, an intermediate pot 31 with a bottom wall 32 and a side wall 33 extending upright from the same is provided, which is arranged between a commercially available planter, preferably in one piece, and the inner pot 3 which holds the plant soil . The intermediate pot 31 essentially corresponds to the shape of the second part 5 of the planter 2, whereby, in contrast to the embodiment according to FIGS. 1 to 3, a bottom wall 32 is arranged directly or near the bottom wall 6 of the first part 4 of the planter 2 . As with the second part 5, the first capacitor electrode 14 and the second capacitor electrode 15 are arranged on the outside of the intermediate pot 31, each of which has a cable 34 protrude from the opening edge of the intermediate pot 31 to the evaluation device 13, not shown. Alternatively, the capacitor electrodes 14, 15 can also be arranged on an inside of the intermediate pot 31.

The intermediate pot 31 differs from the second part 5 essentially in that its shape is adapted to the commercially available planter or the first part 4 of the planter 2. The evaluation device 13 is therefore located outside the planter 2.

The planters 2, 2', the inner pot 3 and the intermediate pot 31 usually have a stop ring 35 on the upper opening edge 23 (Fig. 2).

Claims

Patent claims

1. Soil moisture device for plants with a housing for holding the plants (25) and with a moisture measuring device (1) containing a first capacitor electrode (14, 14 *) and a second capacitor electrode (15, 15 ') and an evaluation device (13) , characterized,

- that the housing is designed in several parts, containing an inner pot (3) for holding the plant soil (24) and a planter (2, 2 ', 2"), which holds the inner pot (3) on a bottom wall (26) of the same and/or on a side wall (27) rising from the bottom wall (26), or o an inner pot (3) for holding the plant soil (24) and an intermediate pot (31) which surrounds the inner pot (3) on a bottom wall (26). of the same and/or on a side wall (27) of the same, and an upper pot (2, 2') which surrounds the intermediate pot (31) on a bottom wall (32) of the same and on a side wall (33) of the same and

- that the first capacitor electrode (14, 14') and the second capacitor electrode (15, 15') are on an outside of a bottom wall and/or a side wall of the planter (2, 2') facing the inner pot (3) and/or of the intermediate pot (31).

2. Device according to claim 1, characterized in that the inner pot (3) consists of a plastic material and that the bottom wall and / or the side wall of the inner pot (3) has perforations. Device according to claim 1 or 2, characterized in that the planter (2) and/or the intermediate pot (31) are designed such that the inner pot (3) fits into the planter (2) or the intermediate pot (31) with play ) can be used. Device according to one of claims 1 to 3, characterized in that the first capacitor electrode (14, 14') and/or the second capacitor electrode (15, 15') are designed to have a large area, covering the outside of the planter (2, 2 ', 2") or the intermediate pot (31) in a circumferential angle (φ ) of at least 40 °, preferably in a range of 160 ° to 170 °, covered. Device according to one of claims 1 to 4, characterized shows that the first capacitor electrode (14, 14') and/or the second capacitor electrode (15, 15') is designed as an electrically conductive film or as a coating which is cohesively bonded to the inside of the planter (2) or of the intermediate pot (31). Device according to one of claims 1 to 5, characterized in that the planter (2) is designed in two parts with a first part (4) and one surrounded by the first part (4). second part (5), a chamber (12) being provided in a lower section (11) facing the bottom wall of the planter (2) for receiving the evaluation device (13) and in an upper section (10) facing away from the bottom wall ) the second part (5) of the planter (2) having the capacitor electrodes (14, 15) is arranged. Device according to one of claims 1 to 6, characterized in that the second part (5) of the planter (2) has opposite grooves (22) on the inside, each of which extends from one bottom wall (8) of the second Part (5) extends to an opening edge (23) of the second part (5). Device according to one of claims 1 to 7, characterized in that the first capacitor electrode (14, 14') and the second capacitor electrode (15, 15') extend in a partially cylindrical or partially conical shape. Device according to one of claims 1 to 8, characterized in that electrical cables (34) connected to the respective capacitor electrodes (14, 14'; 15, 15') protrude from one side of the intermediate pot (31). of such a length that they can be connected to connections of the evaluation device (13). Device according to one of claims 1 to 9, characterized in that the evaluation device (13) is connected to a solar panel (16) and/or to a supercapacitor (17) to supply the evaluation device (13).