NL2001185C2 - Device for recovering moisture present in atmosphere for protecting young plants, has collection structure which is arranged in nested form, is detachably coupled to reservoir for storing recovered moisture - Google Patents

Abstract

The moisture recovering device (1) has a collection structure (8) for collecting moisture present in atmosphere. The collection structure is provided with a water recovery surface (9) that is inclined with respect to orientation of gravity, during use. The collection structure which is arranged in nested form is detachably coupled to reservoir (13) for storing recovered moisture. An independent claim is also included for method for transporting, storing and distributing devices for recovering moisture present in atmosphere.

Description

P83571NL00

Title: Layout and method

The invention relates to a device for recovering moisture present in the atmosphere, comprising a collecting structure with a water extraction surface that during use at least partially makes an angle with respect to the orientation of gravity.

Such a device is for instance known from the

International patent publication WO 2006/132526 for protecting young crops during forest planting.

After planting young crops, there is often a failure due to lack of moisture. This is because the young plant has no or hardly any root structures that are able to absorb water from the subsoil, while the plant does lose moisture due to evaporation. Moreover, the capillary action of the soil is broken by digging a planting hole, as a result of which there is no longer any commissioned water transport from the subsurface. Of course, the failure after planting the young crops entails additional work, such as the removal of dead plant material and the placement of new crops.

The device as described in WO "526 is bulky and therefore expensive in transport, storage and distribution.

The object of the invention is to obtain a device according to the preamble wherein the disadvantages mentioned are obviated while retaining the advantages. In particular, it is an object of the invention to obtain a device which takes up less volume during transport, storage and / or distribution. To that end, the collecting structure can be modularly coupled to a reservoir for storing the collected moisture and the collecting structure can be nested.

By designing the collecting structure and the reservoir in a modular manner and making the collecting structure nestable, a considerable space saving can be realized, while assembly remains relatively simple. This also reduces the costs for transport, storage and / or distribution.

By applying the collecting structure, moisture present in the atmosphere, such as rain, hail, and / or snow, but also water vapor can be recovered relatively easily. The extracted moisture can then be used to supplement the moisture deficit of the plant.

The collection structure collects moisture present in the atmosphere in liquid form, after which the moisture under the influence of gravity reaches lower parts of the water extraction surface. Frozen moisture, such as hail and / or snow, also finds its way to the lower parts of the collecting structure in such a way.

Furthermore, the collecting structure according to the invention is also adapted to recover moisture present in the atmosphere in gaseous phase, namely water vapor. At suitable environmental conditions, such as a temperature of the water extraction surface below the dew point and a sufficiently high humidity of the air, water vapor condenses on the water extraction surface. The water vapor precipitates in the form of moisture drops on the receiving surface. The moisture droplets slide down under the influence of gravity. While the moisture droplets slide downwards, their size increases, since the condensed droplets merge through cohesion. Since relatively much moisture can be extracted from the atmosphere in this way, relatively much moisture can also be supplied to the young plant to supplement the shortage of moisture, so that failure of the young plant will decrease. When extracting moisture present in the atmosphere, only passive structures are used which during use do not consume external energy and do not comprise any moving parts.

It is noted that a young plant is understood to mean a young plant at an early stage, such as a cultivated plant, young tree or shrub, but also, on the contrary, germinated plant material, a seed or a spore.

3

The upper side of the water extraction surface is furthermore preferably provided with an adhesion-reducing additive and / or cover layer, for example of PET and / or teflon, and / or by applying small irregularities and / or roughening, optionally with an addition of but not limited to a wax layer, a silicone or teflon product or another adhesion-reducing substance, so that a water-repellent effect is obtained because the mutual cohesion of water increases and / or the adhesion of water on the surface of the instrument decreases, thereby forming larger drops. As a result of this, namely due to the weight increase of the drops, as a result of the increased weight and thereby increased sensitivity to gravity and due to the relatively lower adhesion due to the larger droplets, they can more easily reach the lower parts of the water extraction surface, so that the amount of moisture gained increases.

Advantageously, the opening angle of the water extraction surface is turned away from the earth as much as possible during operation, so that infrared radiation to the space is stimulated as much as possible. The temperature of the water extraction area will fall as a result. Furthermore, by providing the water extraction surface on the underside with thermal insulation, for example by applying insulating material and / or by creating an air buffer in an isolation chamber, the infrared radiation of heat from the water extraction surface is less quickly compensated by heat from below the water extraction surface share. As a result, heat supply to the water extraction area remains limited. In other words, the heat absorption of the water extraction surface is relatively slow. As a result, a temperature difference between the water extraction surface and the surrounding air can be established relatively quickly and can be maintained for a relatively long time, for example on a clear and / or cool night. By applying insulation, for example by preventing hot air from coming into contact with the water extraction surface, the water extraction surface retains a relatively low temperature for a long time, also when the temperature of the ambient air increases, so that the condensation process, whereby hot air flowing past cools down and condensation occurs, lasts relatively long and with it also the water extraction process. Thus, the temperature of the surface follows the temperature trend on cooling faster and the temperature curve on heating the surrounding air slows down. As soon as warm air comes in contact with the cold water extraction surface, the warm air is cooled, so that the dew point is reached and condensation occurs. In this case occurring dew drops on the water extraction surface. In order to maintain temperature differences between the air and the leaf as long as possible, the water extraction surface can also be provided with or consist entirely of material that has a high specific heat.

Because the water extraction surface of the collecting structure is oriented substantially upwards, the structure loses heat due to radiation. As a result, the temperature of the water extraction surface decreases, so that moisture present in the atmosphere condenses on the structure, which then has a lower temperature than the ambient air. This natural process, also called "publishing", is utilized by the device 20 according to the invention. The choice of materials and geometry is aimed at allowing the water extraction surface to cool and keep cool in order to prevent heating of said surface.

The invention further relates to a method for transporting, storing and / or distributing devices for collecting moisture present in the atmosphere.

Further advantageous embodiments of the invention are shown in the subclaims.

The invention will be further elucidated on the basis of exemplary embodiments shown in the drawing. In the drawing 30 shows: 5

Figure 1 is a schematic cross-sectional view of a first embodiment of a device according to the invention;

Figure 2 shows a schematic cross-sectional view of a first embodiment of the water extraction surface of the device of Figs. 1;

Figure 3 is a schematic cross-sectional view of a second embodiment of the water extraction surface of the device of Figs. 1; Figure 4 is a schematic cross-sectional view of a second embodiment of a device according to the invention;

Figure 5 is a schematic perspective view of a third embodiment of a device according to the invention in a partially cut-away state;

Figure 6 is a schematic cross-sectional view of two nested devices of Figure 5;

Figure 7 is a schematic perspective partial view of the water extraction surface of the device of Figure 5; Figure 8 is a schematic perspective view of a fourth embodiment of a device according to the invention;

Figure 9 is a schematic perspective view of a fifth embodiment of a device according to the invention;

Figure 10 shows a first schematic perspective view of a sixth embodiment of a device according to the invention; and

Figure 11 is a second schematic perspective view of the device of Figure 10.

The figures are only schematic representations of the invention and are only given by way of non-limiting exemplary embodiments.

6

Figure 1 shows a schematic side view of a first embodiment of a device 1 for recovering moisture present in the atmosphere according to the invention. The device 1 comprises a tube 2 which surrounds a young plant 3 sideways such that the young plant 3 is at least partially enclosed laterally. The tube 2 is open at the top and bottom, so that the plant can take root downwards and can grow upwards. The young plant 3 is rooted in a pressing ball 4 which is positioned in the tube 2 in such a way that the root structure 4a of the plant 3 is surrounded by the tube 2, while the underside of the stem 10 is situated at the lower edge of a later described water extraction area. The plant 3 is thus in the light and sufficient air flowing past is available. The press ball 4 comprises a substance, for example soil or substrate, and is clamped in the opening of the tube wall 2. The substance is optionally provided with symbiotic bacteria, eggs from animals, seeds, fungi, spores, and / or organic and / or inorganic materials for feeding the plant 3, the so-called grafting. If the device 1 is made of biodegradable organic material, a grafting can also be provided in this material. For an improved stability, the pressing ball 4 can optionally be further arranged at the bottom of the tube 2.

The device 1 further comprises at least one inoculation cocoon 5 for supplying nutrients to the young plant 3. The inoculation cocoon 5 is preferably located in the press ball 4 enclosed by the tube 2 and comprises at least one package which under the influence of erosion and / or 25 bacterial activity during a longer period, for example months or years, is interrupted. The packages contain material that stimulates the growth of the plant 3 and / or improves the condition of the plant 3, such as, for example, nutrients and / or symbiosis bacteria. By applying packages with different degradation periods, the substances present therein are metered at the disposal of the plant 3, so that 7 can be administered autonomously to the plant 3 over a relatively long term. The vaccination cocoon can for instance be provided with different degradation layers. However, it will be clear to the skilled person that instead of a vaccination cocoon 5 other means can be used to feed the plant, such as the previously described materials in the press ball 4.

The sleeve 2 is placed on the surface 6 of a substrate 7. The substrate 7 is preferably not previously processed or only slightly scraped, so that the capillary 23 of the substrate 7 is not broken.

This prevents unnecessary evaporation of moisture present in the substrate 7. Moreover, this stimulates that a constant supply of moisture continues to take place from the subsurface upwards by means of the unbroken capillary. Less erosion also occurs. Moreover, the method described above saves labor-intensive operations, such as, for example, digging a hole in the ground. After placing the plant tube 2, the young plant 3 roots in the substrate 7 and comes into direct contact with the capillary moisture 23, so that the plant receives a daily constant amount of moisture from both the substrate 7 and from the plant tube.

It is otherwise possible to process the substrate 7 in advance, so that the root structure of the plant can be brought into the substrate 7. As a result, the chance of successful planting of the plant 3 with sufficient moisture present can increase and an even lower failure can be expected.

The device 1 further comprises a substantially funnel-shaped collecting structure 8 with a water extraction surface 9 which comprises receiving and collecting surfaces 10, 11 which are discussed in more detail with reference to Figures 2 and 3. The water extraction surface 9 is for instance formed from polypropylene or a other plastic, and is provided with an adhesion-reducing cover layer and / or made of water-repellent material or otherwise chemically and / or mechanically processed so that the surface is water-repellent to prevent the sticking of water droplets to the surface 9 and cohesion between the water droplets themselves to improve. The water extraction surface can thus be at least partially water-repellent, for example by applying a roughening process. By applying a roughening on a nanometer scale, the contact surface with water droplets on it is relatively small, so that adhesion forces are also relatively small. This allows water droplets to move relatively easily under the influence of the gravitational field. The roughening process may, for example, comprise a laser and / or etching process. In addition, the water extraction surface can be provided with a silicone top layer, so that an even higher water-repellent effect is obtained. By using waxy substances, water droplets can, even when the surface is oriented almost transversely to gravity, slide downwards and be collected in a reservoir described below. Collecting surfaces 11 all, only partially or not at all, flow into the tube 2, so that extracted moisture from the atmosphere, such as rain of condensed water, can possibly directly benefit the young plant 3. Furthermore, there are openings in the water extraction surface. 12 are provided which serve as inlet points for the passage of moisture on the water extraction surface 9 to a reservoir 13 located below the collecting structure, so that the collected moisture can be stored. By arranging the reservoir substantially below the water extraction surface, the extracted water can remain relatively cool, so that undesired evaporation is prevented. Moreover, a relatively stable construction is hereby obtained which falls over less easily with the occurrence of, for example, windbreaks. The young plant is thus better protected against external influences.

The reservoir 13 rests on the surface 6 of the substrate 7, so that a stable position of the device 1 is obtained. Furthermore, by covering the environment of the young plant by the device, the growth of plant material in the immediate vicinity of the young plant 3 is prevented, so that as much light as possible and available nutrients in the substrate 7 benefit the young plant. 3. The presence of the reservoir 13 also limits evaporation of moisture from the substrate around the plant 3. In the reservoir 13 shown an amount of moisture 19 is already present. The reservoir 13 is provided with irrigation means designed as one or a plurality of irrigation points for releasing moisture present in the reservoir 13 to the underlying substrate 7.

The irrigation point shown is designed as a hollow needle 14 which acts as a dropper. With the aid of the hollow needle 14, the moisture present in the reservoir 13 can be metered into the substrate 7, so that sustainable fresh water supply is realized. The reservoir 11 with the irrigation point also makes it possible to still release relatively large amounts of rainwater collected in a relatively short time to the substrate 7. The hollow needle 14 also serves as an anchor for further raising the stability of the device 1. Of course, it is possible to implement the irrigation point differently, for example as an opening in the bottom 16 of the reservoir 13, or as one or a plurality of capillary cords. A capillary cord can for instance comprise cotton and / or fibers. Optionally, the dosage of the flow rate of the moisture to be delivered to the substrate 7 is adjustable with the aid of control means. The control means comprise, for example, a permeable membrane or a membrane which is arranged in the passage of the hollow needle 14. When a capillary cord is used, for instance a pinching instrument, such as a swivel, can be used. The control means may also comprise movable covering means. Furthermore, the capillary can extend through an opening in the wall of the reservoir, wherein the distance from the projecting part is varied to set a flow. The control means may also comprise one or a plurality of conically shaped elements which can completely or partially close corresponding openings in the bottom of the reservoir. A flow rate of moisture to be delivered can thus be set.

The reservoir 13 comprises an outflow channel 15, also referred to as an overflow pipe, a first end 17 of which is located above the bottom 16 of the reservoir 13 during use and of which a second end 18 connects to the irrigation point, in the embodiment shown the hollow needle 14 By using the overflow pipe 15 it is achieved that solid particles in the stored moisture 19, such as dirt and / or dust, which lie on the bottom 16 of the reservoir 13 up to the level of the first end 17 of the overflow pipe 15 do not reach the subsurface 7 via the irrigation points. This prevents blockage of the irrigation points. The overflow pipe 15 thus functions as a simply arranged filter for settled solid particles in the stored moisture 19.

The control means can for instance also comprise a permeable membrane, a capillary cord or a membrane which is arranged in the passage of the hollow needle 14.

Moreover, the reservoir 13 is provided with an overflow opening 21 in the tube 22 of the reservoir 13, so that excess moisture can easily flow away. The overflow opening 21 is positioned just above the level of opening 12.

Thermal insulation material 20 is provided below the water extraction surface 8, so that a temperature difference between the water extraction surface 9 and the surrounding atmosphere is maintained for as long as possible to promote the moisture recovery process. The underside of the insulating material 20 can be designed both horizontally and concretely or convexly, a concave shape counteracting the evaporation of the moisture stored in the reservoir 13.

Furthermore, the device 1 is provided on the outside with eyes 29. An anchor pin 30 can be provided through the eyes 29 for anchoring the device to the substrate 7. Optionally a pin 31 is provided on the pin 11 at different distances which can engage on an eye of the establishment. This allows a pin to carry the device at a desired height. The orientation of the device can also be adjusted, so that the aid can be positioned substantially horizontally above a sloping surface. The eyes are preferably evenly distributed over the circumference of the device, for example every 90 °. The pin is further optionally provided with arms that extend substantially sideways, so that the pin can be stabilized sideways against the surface 6 of the substrate 7.

The water-winning surface 9 forms a collecting structure 8 for recovering moisture present in the atmosphere. The water-winning surface 9 herein makes an angle with respect to gravity orientation during operation of the device 1. According to an aspect of the invention, the collecting structure 8 is modularly coupled to the reservoir 13. Furthermore, the collecting structure 8 is nestable.

Since the collection structure can extend laterally beyond the tube of the device, the effective area for receiving the moisture is increased. As a result, more water becomes available for the young plant than the inner space of the tube could collect on its own in terms of precipitation.

By extracting water from the atmosphere by means of condensation, it is also possible to plant relatively dry and / or rocky areas. Soils that contain salt or brackish water are also suitable for planting, since the increased available moisture content can form segments in the subsoil with fresh water. In addition, plants and trees can be planted at an early stage, since the organism is better protected and cared for by the device according to the invention than in the case of the known plant aid. Of course, this has the advantage that fewer costs are involved in obtaining the younger 12 plants. Moreover, transport costs are lower. Due to the constant water supply, the young plant can be planted on the soil instead of in a planting hole to dig. As a result, the capillary of the soil is not disturbed and can also be planted on rocky soils.

It is further noted that the tube surrounds the young plant at least partially sideways. It is of course possible to design the tube closed all-round, so that the tube completely encloses the plant. However, it is also possible to leave an opening or a gap free, for example for applying germinating material in the tube, after the device has been positioned on the substrate. The young plant is preferably arranged such that the sleeve surrounds at least partially the root structure or root structure to be formed. The stem, trunk, branches and / or foliage is then substantially above the upper edge of the tube, so that sufficient air flowing past is available for the plant. Of course, it is also possible to position the young plant differently, for example with the foliage at least partially below the upper edge of the tube, so that a better mechanical protection of the young plant is obtained.

The device according to the invention thus functions not only to protect physical influences from outside, but also to support the plant and to stimulate growth of the young plant.

By designing the water extraction surface in a substantially funnel-shaped manner, the moisture obtained can easily be led to the inside of the tube, so that the moisture benefits the plant.

Moreover, a relatively large amount of day and / or sunlight and / or ventilation is available for the young plant so that fungal growth is prevented and assimilation and / or ventilation processes are minimally influenced. The water extraction surface can, however, be designed differently, for example as a truncated cone which has the largest diameter at the bottom.

The moisture obtained can thereby be collected at the edges.

13

Figures 2 and 3 show a schematic side view of a first and a second embodiment of the collecting structure 8 of the device 1, respectively, which functions as a planting aid. The collecting structure 8 has a water extraction surface 9 which is oriented substantially upwards for the recovery of moisture present in the atmosphere. Due to a specific structure, the water extraction surface 9 comprises at least one receiving surface 10 and at least one collecting surface 11 for respectively obtaining and collecting the moisture. The receiving surface 10 makes a first angle α with respect to the orientation of gravity Z. The collecting surface 11 makes a second angle B with respect to the orientation of gravity Z. The first angle α is smaller than the second angle B, so that droplets on the receiving surface 10, in principle, slide down faster than droplets on the collecting surface 11. Since the collecting surface 11 borders on a lower edge 10a, relatively many droplets will collect near the collecting surface 11 and will form larger drops due to cohesion forces. Larger drops experience relatively less adhesion forces from the water extraction surface 9, so that a second angle B that is larger than the first angle α is sufficiently steep to lower the drops down along the collecting surface 11 into the tube 2 or into an opening 12 towards the reservoir. 13 to slide.

By making the surface of the water extraction surface 9 particularly water-repellent, as described above, an effective device for extracting moisture present in the atmosphere can also be obtained, wherein the water extraction surface 9 comprises only surfaces that are at one predetermined angle with respect to the gravity direction.

It is noted that a water extraction surface with surfaces oriented only at one predetermined angle relative to the direction of gravity can not only be used with the device 30 according to claim 1, but also more generally in combination with an extraction device of moisture present in the atmosphere, comprising a collecting structure with a water extraction surface that during use at least partially makes an angle with respect to the orientation of gravity, wherein the water recovery surface is designed to be water-repellent.

Water droplets on the receiving surface 10 are obtained by collecting precipitation and / or water droplets obtained from the atmosphere by the water extraction process, such as by dew and / or condensation, where the receiving surface 10 acts as a condensing surface. Solid precipitate is collected and collected in the same way as wet precipitate.

Optionally, the device 1 can be reused. However, it is also possible to manufacture the device 1 from (biodegradable) material, such as biopolymers, so that dismantling operations remain limited or are completely unnecessary. In the latter situation, the device 1 can advantageously be provided with at least one inoculation cocoon 5. Moreover, the device can subsequently serve as compost and / or comprise growth-promoting means.

The device is preferably made opaque, non-transparent, so that weed formation within the device is prevented.

Figure 4 shows a schematic cross-sectional view of a second embodiment of a device 1 according to the invention.

The second embodiments is substantially in the same way as the first embodiment as described with reference to Figures 1-3. In Figure 4, the reservoir 13 comprises an inlet pipe 60 which connects with a first end 61 inwardly to the edge of opening 12 in the water recovery area 9. By using such an inlet pipe 60, loss of moisture present in the reservoir 13 by evaporation becomes considerably reduced. Namely, the amount of moisture that can evaporate generally increases as the size of the liquid surface that is in gas communication with the aperture 12 increases. Conversely, the amount of liquid lost by evaporation decreases as the size of the liquid surface in gas communication with the opening decreases. Since the liquid surface in the inlet pipe 60 is much smaller than the other liquid surface in the reservoir 13, the evaporation through the opening 12 is correspondingly smaller, and thus also the loss of moisture through evaporation from the reservoir 13. Thus, the liquid forms in the inlet pipe 60 a moisture barrier that evaporates from the remaining liquid surface in the reservoir 13.

Because the inlet pipe 60 with a second end 62 reaches just above the bottom 16 of the reservoir 13, the inlet pipe 60 also functions if only a small amount of moisture is present in the reservoir, because the second end 62 of the pipe 60 then still below the liquid surface.

The inlet pipe 60 is preferably tapered in the direction of the first end 61, so that blockages at the bottom of the inlet pipe are advantageously prevented.

Furthermore, the reservoir 13 comprises an overflow pipe 70 which, similarly, connects with a first end 71 to the edge of the outflow opening 21 and extends with a second end 72 to just above the bottom 16 of the reservoir 13, so that evaporation of moisture through the Outflow opening 21 is prevented. In order to prevent blockages in the overflow pipe 70, the pipe can be constructed such that the pipe tapers towards the first end 61, as is the case with the inlet pipe 60.

Also in the second embodiment of the device 30 according to the invention, as shown in Figure 4, the 16 collecting structure 8 is modularly coupled to the reservoir 13 and the collecting structure 8 is designed to be nestable.

Figure 5 shows a schematic perspective view of a third embodiment of a device according to the invention in a partially cut-away state.

The device 1 comprises a collecting structure 8 with a water extraction surface 9 which during use at least partially makes an angle with respect to the orientation of gravity. Furthermore, the collecting structure 8 is modularly connectable to the reservoir 13. The water extraction surface 9 is, as in the first and second embodiment, provided with a receiving surface 10 and a collecting surface 11.

The device 1 further comprises a tube 2 which can at least partially surround a young plant. The sleeve 2 and the reservoir 13 are integrally formed, so that a saving is achieved in the number of components required for assembling the device 1. The integrated sleeve and reservoir can be coupled to the receiving structure as a module. The sleeve and the reservoir on the one hand and the collecting structure on the other are preferably coupled to each other in a moisture-tight and / or airtight manner, so that no moisture is lost. In addition, the modules are preferably detachable, so that the device can easily be dismantled. Furthermore, the coupling between the modules is preferably such that a minimal heat exchange takes place. This allows the water extraction surface to be kept cool.

The collecting structure 8, the tube 2 and / or the reservoir can for instance be made of plastic. Hereby, advantageously use can be made of an injection molding process or comparable manufacturing processes.

More preferably, the integrated sleeve and reservoir are also designed to be nestable, so that the modules can be stored, transported and distributed in a compact manner, for example in units of a few tens or hundreds. Even when the sleeve and the reservoir are of separate design, the sleeve and / or the reservoir can be designed to be nestable. Figure 6 shows a schematic cross-sectional view of two nested devices of Figure 5. Here, two reservoirs, each of which is integrated with a tube, are nested, while also two collecting structures are nested.

Advantageously, the angle that a wall segment of the tube, the reservoir and / or the receiving structure makes with respect to the direction of gravity during use can be minimized in dependence on the wall thickness. Said angle can thus be chosen smaller as the wall thickness decreases. A compact storage possibility is hereby created for the modules of the device, while the largest possible volume is also available for the reservoir. In a practical embodiment, the wall 113 of the reservoir 15 has, for example, an angle of approximately 6 ° to 10 ° with respect to the direction of gravity.

In the embodiment shown, the sleeve is tapered, such that the sleeve has the largest diameter at the lowest point, on the side opposite the receiving structure. As a result, the device can easily be removed after a period of time with little chance that the plant or parts of the root ball are thereby pulled along in upward direction. In principle, the device is therefore self-releasing.

Optionally, the sleeve, the reservoir and / or the collecting structure are of two or more parts, so that individual parts can be removed by uncoupling. As a result, even after longer periods of time, when branches and foliage have been formed that extend sideways and / or upwards, the device can be dismantled relatively easily without damaging the plant. The individual parts can for instance be mutually attached with a click system. Of course, other fixing techniques are also applicable, for example a suspension system. Furthermore, the device cannot be of a completely closed design, in top view, but can for instance substantially form a U-profile, so that the whole can easily be pulled away laterally.

The dimensions of the device and / or its modules 5 are preferably chosen such that the space on a pallet can be optimally utilized. A length-width ratio of, for example, approximately 40 cm by approximately 60 cm, approximately 50 cm by approximately 60 cm, approximately 80 cm by approximately 60 cm and approximately 100 cm by approximately 60 cm can be chosen.

It is noted that the device can alternatively be manufactured from relatively heavy material, for example from cement and / or metal. The device can hereby also serve as protection against mechanical external influences, so that damage to the plant can be prevented.

The side wall of the reservoir 13 can at least partially be made transparent, so that harmful bacteria can be rendered harmless under the influence of UV radiation. Moreover, the liquid level can then be easily determined visually. Alternatively or additionally, agents may be added to the collected moisture to control, for example, bacteria, such as legionella bacteria.

Furthermore, the sleeve 2, the reservoir 13 and / or the receiving structure 8 can be provided with stiffening ribs, so that a predetermined stiffness can be realized with a relatively small wall thickness. Advantageously, the reservoir 13 can be asymmetrical in plan view. This achieves that the reservoir 13 is nestable on the one hand and, on the other hand, when stacking alternately, just the bottom of a reservoir is supported by an upper edge of the reservoir positioned below it. By thus making the reservoir stackable and nestable at the same time, the reservoir can also fulfill another function, for example as a storage box.

19

Below the water extraction surface 9 is an insulation chamber 110 for insulating said surface. This keeps the water extraction surface cooler longer when underlying structures heat up. The insulation chamber is bounded at the top by the water extraction surface. Furthermore, the insulating chamber 110 is bounded laterally by a downwardly oriented flange 111 of the collecting structure 8. The underside of the insulating chamber 110 is formed by a plate-shaped element 112 which is arranged modularly above the reservoir: By using the plate-shaped element 112 it is possible in a simple manner an isolation chamber can be formed.

If desired, insulating material can be provided in the isolation chamber 110. However, it is also possible that air present in the chamber 110 serves as insulation.

It is noted that parts of the water extraction surface are oriented at a relatively large angle with respect to the direction of gravity, so that the radiating effect of the surface is utilized as much as possible.

Furthermore, the reservoir is provided with a refill opening 114 for optionally manual or machine refilling of the reservoir. This allows a young plant to be supplied with more liquid than is available on the basis of moisture extracted from the atmosphere. Other ingredients can also be added in this way, for example nutritional supplements. The refill opening is advantageously accessible via the collecting structure. By arranging the refill opening relatively high, a maximum space for the reservoir can be utilized.

Figure 7 shows a schematic perspective partial view of the water extraction surface 9 of the device as shown in Figures 5 and 6. The refill opening 114 is located near the lowest point of the water extraction surface 9, so that a maximum space is also available for the isolation chamber. In the embodiment shown, the lowest point is approximately 20 in the middle of the water extraction surface, near the tube 2.

A gutter 115 is located around the tube, into which the collected moisture ends up, such that it is led via the inlet pipe 60 to the reservoir 13. An upright edge 117 is provided on the radial inner side of gutter 115, so that an additional water storage on the water extraction surface is realized.

By using the raised edge 117 near lower parts of the water extraction surface, the water extraction surface, for example during and immediately after a heavy rain shower, can serve as a temporary water reservoir. In the case of heavy rainfall, the amount of rainwater recovered per unit of time can be greater than the drainage capacity from the water extraction area to the reservoir. The rainwater collected in the temporary water reservoir can then be drained afterwards via opening 12, possibly provided with an inlet pipe 60, to the actual reservoir. In the absence of the raised edge 117, an excess of rainwater would flow directly into the tube and thus be lost to be supplied to the plant via the reservoir at a later stage.

It is noted that forming the water extraction surface such that it can also at least partially serve as a temporary reservoir for moisture collected by the device can not only be used with the device according to claim 1, but also more generally in combination with a device. device for recovering moisture present in the atmosphere, comprising a collecting structure with a water extraction surface that during use at least partially makes an angle with respect to the orientation of gravity.

Advantageously, the filling opening 114 can be closed by a filling cap 116 which is preferably airtight. To this end, the filler cap can for instance be sealed to a diameter and comprise a bayonet closure. Of course, countless alternatives are conceivable, for example with the aid of sealing rings. However, by sealing the filler cap to diameter, a substantially airtight seal can be obtained in an elegant manner with a single element.

In the embodiment shown, the refill opening 114 is realized by designing the plate-shaped element 112 with an opening. Since the opening 114 is realized near the lowest point of the water extraction surface 9, the reservoir is directly accessible from the water extraction surface 9 and no additional provisions such as an additional tube or the like are required.

It is noted that a reservoir provided with a refill opening can not only be used with the device according to claim 1, but also more generally in combination with a device for recovering moisture present in the atmosphere, comprising a collecting structure with a water extraction surface that makes at least partially an angle with respect to the orientation of gravity during use.

Figures 10 and 11 show a first and second schematic perspective view of a sixth embodiment of a device according to the invention. The device broadly corresponds to the third embodiment of a device according to the invention as shown in Figures 5-7. The device is thus provided with a collecting structure 8 with a water extraction surface 9. The collecting structure 8 is coupled to the reservoir with reservoir wall 13. Furthermore, the water extraction surface 9 comprises an overflow structure for discharging an excess of collected moisture outwards. The overflow structure has an overflow path, the highest path of which, viewed in the direction of gravity, is lower than the top of the upstanding tube edge 117. Thus, the overflow path forms a path for an excess of moisture from lower parts of the water extraction surface 9 to 30 outside the side edge 122 of the establishment. As a result, an excess of 22 collected moisture, for example during a severe control fall, which threatens to flow into the tube, can be discharged outward.

If much moisture is recovered in a short time, the moisture runs through the trough 115 and the inlet pipe 60 into the reservoir. When the inlet pipe 60 can no longer process the collected moisture, a temporary storage space is created on the lower part of the water extraction surface 9, the raised edge 117 around the tube preventing the moisture from flowing into the tube, as described above. If the moisture level in the temporary storage space rises even further, so far that the moisture nevertheless threatens to flow over the upright edge 117, the excess moisture flows out via the overflow structure, so that an excess of moisture is still prevented. tube flows. The moisture flows outwardly from the device via one or a plurality of overflow paths of the overflow structure.

The overflow structure shown in Figs. 10 and 11 is implemented as a channel 120, the highest path 121 of which is near the outer edge 122 of the water extraction surface 9. In the embodiment shown, the channel 120 runs through the outer edge 122. Of course, it is also possible to Overflow structure to be constructed differently, for example as a multiple number of channels, so that a more stable situation arises in the event of a sudden overflow. When the channels are arranged at different, preferably opposite, segments of outer edges 122, the excess moisture can also flow outwardly when the device is not positioned completely vertically.

The channel 120 is located in a lower part of the water extraction surface 9, in the embodiment shown in a collecting surface. As a result, relatively little or no surface area of receiving surfaces is lost, and therefore receiving capacity of the device.

23

Optionally, the reservoir is designed in an advantageous, more simple manner without overflow pipe 70, since a structure has already been provided on the water extraction surface for removing excess moisture.

It is noted that a water extraction surface comprising an overflow structure to discharge an excess of trapped moisture outwards can not only be used with the device according to claim 1, but also more generally in combination with a device for collecting moisture present in the atmosphere 10, comprising a collecting structure with a water extraction surface that during use at least partially makes an angle with respect to the orientation of gravity.

The invention is not limited to the exemplary embodiment described here. Many variants are possible.

The water extraction surface can thus be designed in different colors. By providing the surface with a light color, the heat absorption by means of sunlight is relatively low, so that a condensation process for recovering water remains effective for a relatively long time.

Furthermore, the collecting structure can not only be used in combination with a plant aid, but can also be used independently for collecting moisture present in the atmosphere, for instance with the aid of fastening means for mounting on buildings, vessels, such as sailing ships, or on other floating structures offshore . The recovered moisture can be processed to obtain drinking water or otherwise, for example for chemical processes and / or irrigation purposes.

Figure 8 shows a schematic perspective view of a fourth embodiment of a device 200 according to the invention. In this case, the collecting structure 208 with the water extraction surface 209 as a roof is attached to a dwelling 210, so that precipitation and other moisture extracted from the atmosphere can be collected. The reservoir 24 is designed as a vessel 211 connected to the water extraction surface 209. Furthermore, the vessel 211 is provided with a tap 212 for draining the collected moisture. It is noted that such a device can also be applied to other types of utility construction, such as offices or industrial buildings. Due to the rib structure of the receiving structure 208 a particularly rigid whole has been obtained which is thus relatively resistant to shocks, such as earthquakes or earthquakes.

Figure 9 shows a schematic perspective view of a fifth embodiment of a device 300 according to the invention. The collecting structure 308 with the water extraction surface 309 is attached to the top of a bottle 310 which serves as a reservoir. Consequently, moisture can be recovered in an elegant and easy manner and stored in a bottle, for example a bottle for soft drinks. Advantageously, the underside of the collecting structure 308 can be provided with a screw thread which corresponds to the screw thread of the bottle, such that the collecting structure can be turned on the bottle as a cap.

A simple, robust and watertight connection to the bottle is hereby obtained. The collecting structure 308 is hereby modularly coupled to the reservoir which is designed as a bottle 310 by means of a screw connection with corresponding dimensions. Naturally, other coupling techniques of the collecting structure and the bottle are also possible, for example a snap connection. The bottle with collection structure can be placed on or in the ground. When placed in the ground, the downwardly oriented flange 311 of the water extraction surface 309 forms a side edge of an isolation chamber as described above when the bottle is buried in the ground. However, the water extraction surface 309 can in principle also be designed without a downwardly oriented flange 311, for example to simplify the manufacturing process of the collecting structure 308.

25

Use of a device according to the invention is furthermore possible by placing above salt or brackish water, since condensation of evaporated salt or brackish water leads to freshwater production.

Optionally, a mesh structure 5 is provided above the water extraction surface, so that feeding of the plant is prevented by animals that reside in the vicinity of the device.

Such variants will be clear to those skilled in the art and are understood to be within the scope of the invention as set forth in the following claims.

Claims (36)

A device for recovering moisture present in the atmosphere, comprising a collecting structure with a water extraction surface that during use at least partially makes an angle with respect to the orientation of gravity, the collecting structure being modularly connectable to a reservoir for storing the extracted moisture and where the collection structure is nestable. Device as claimed in claim 1, further comprising a tube connectable to the collecting structure for at least partially sideways surrounding a young plant that can be placed in the collecting structure. Device as claimed in claim 2, wherein the sleeve and the reservoir are integrally formed. Device as claimed in any of the foregoing claims, wherein the sleeve and / or the reservoir is also designed to be nestable. 5. Device as claimed in any of the foregoing claims, wherein the reservoir surrounds the tube at least partially. Device as claimed in any of the foregoing claims, wherein the angle that a wall segment of the tube, the reservoir and / or the collecting structure makes during use with respect to the direction of gravity is minimized in dependence on the wall thickness. Device as claimed in any of the foregoing claims, wherein the collecting structure is modularly coupled to the reservoir. 8. Device as claimed in any of the foregoing claims, wherein the water extraction surface comprises a receiving surface which during use makes a first angle with respect to the orientation of the gravity, and a collecting surface adjacent to a lower edge of the receiving surface which makes a second angle during use relative to the orientation of gravity, the first angle being smaller than the second angle. Device as claimed in any of the foregoing claims, wherein the water extraction surface is substantially funnel-shaped. Device as claimed in any of the foregoing claims, wherein the reservoir is situated substantially below the water extraction surface. Device as claimed in any of the foregoing claims, wherein an isolation chamber is located under the water extraction surface. 12. Device as claimed in any of the foregoing claims, further comprising a plate-shaped element which is arranged modularly above the reservoir to form at least a part of the underside of the isolation chamber. Device as claimed in any of the foregoing claims, further comprising insulation material which is arranged under the water extraction surface. 14. Device as claimed in any of the foregoing claims, wherein the receiving structure comprises a downwardly oriented flange to form a side wall of the isolation chamber. Device as claimed in any of the foregoing claims, wherein the reservoir is provided with a refill opening. 16. Device as claimed in any of the foregoing claims, wherein the refill opening is accessible via the collecting structure. Device as claimed in any of the foregoing claims, wherein the refill opening is located near the tube and / or near the lowest point of the water extraction surface. 18. Device as claimed in any of the foregoing claims, wherein the refill opening is formed by a recess of the modular plate-shaped structure arranged above the reservoir which connects to a recess in the receiving structure. Device as claimed in any of the foregoing claims, wherein the sleeve, the reservoir and / or the collecting structure is provided with stiffening ribs. Device as claimed in any of the foregoing claims, wherein the reservoir is shaped asymmetrically in top view. 21. Device as claimed in any of the foregoing claims, wherein the sleeve is substantially tapered with the largest diameter on the side opposite the receiving structure. Device as claimed in any of the foregoing claims, wherein the receiving structure is provided with a downwardly oriented flange to form a side wall of the isolation chamber. 23. Device as claimed in any of the foregoing claims, wherein the side wall of the reservoir is at least partially transparent. Device as claimed in any of the foregoing claims, wherein the water extraction surface is formed at least partially water-repellent. Device as claimed in any of the foregoing claims, wherein the water extraction surface has undergone a roughening process. Device according to any of the preceding claims, wherein the water recovery surface comprises an adhesion-reducing top layer, which optionally comprises a silicone or Teflon material. 27. Device as claimed in any of the foregoing claims, wherein parts are built up from biodegradable material. Device as claimed in any of the foregoing claims, wherein the reservoir is provided with irrigation means for delivering moisture present in the reservoir to an underlying substrate. 29. Device as claimed in any of the foregoing claims, wherein the irrigation means are provided with control means for controlling a flow of moisture to be delivered. Device as claimed in any of the foregoing claims, wherein the collecting structure is provided with an upstanding edge adjacent to lower parts of the water extraction surface. 31. Device as claimed in any of the foregoing claims, wherein the raised edge forms the upper edge of the tube. Device as claimed in any of the foregoing claims, wherein the water extraction surface comprises an overflow structure for discharging an excess of collected moisture outwards. Device as claimed in any of the foregoing claims, wherein the overflow structure has an overflow path of which the highest path, viewed in the direction of gravity, is lower than the top of the raised edge. 34. Device as claimed in any of the foregoing claims, wherein the overflow path forms a path from lower parts of the water extraction surface to outside a side edge of the device. 35. Method for transporting, storing and / or distributing devices for extracting moisture present in the atmosphere, each of the devices comprising a collecting structure with a water extraction surface that at least partially makes an angle with respect to the orientation of gravity wherein the collecting structure is modularly connectable to a reservoir for storing the recovered moisture and wherein the method comprises nesting the collecting structures. 36. Method for adding bactericidal agents to a reservoir in which moisture extracted from the atmosphere is stored.