DE102016222326B3 - Plant cultivator and method for growing plants - Google Patents

Abstract

Plant cultivator and method for growing plants. The plant cultivator has a closed housing with at least one cooling device to cool at least a predetermined area within the housing. The at least one cooled cooling device is configured to recondense and transfuse water transpired from the plants and / or evaporated from a substrate at the at least one cooled area.

Description

The present invention relates to a plant cultivator for growing plants and a corresponding method of growing plants using a plant cultivator. More particularly, the present invention relates to the recycling of water transpired from plants and / or from plant substrate.

Plant cultivators that provide extensive control and regulation of the cultivation environment are known in the art. In particular, the describes DE 102 30 133 A1 a plant cultivator for research and a control system used in experiments to find the optimal cultivation environment for plants.

The devices of the prior art have the disadvantage that they have very complicated constructions with a wealth of media (such as, for example: cooling water, demineralized water, compressed air, duct connection, etc.) or external components and units. For these reasons, such plant cultivators are also preferably used in the field of research and are unsuitable for other uses.

Furthermore, the known plant cultivators are very difficult to clean due to the complex construction and generally very expensive. Due to the many external components, aggregates and media of such plant cultivators, the risk of damage is increased.

In addition, most known plant cultivators require active humidification by externally connected piping systems. Due to the moisture in these pipes, it often comes to bacterial or fungal attack. Cleaning the pipes with special chemicals is therefore necessary at regular intervals.

Active humidification and irrigation in the known plant cultivators usually also requires active control by a computer or microcontroller system. This increases both the complexity and the cost of the plant cultivator. Other components, such as pumps, valves, additional sensors, etc. are also necessary in an active humidification / irrigation and affect the aforementioned parameters negative.

Almost all known plant cultivators transport excess moisture via fans into the installation room - this ventilation with ambient air makes precise CO ₂ fertilization virtually impossible. Also, the conditions in the interior of the cultivator in this type of construction are highly dependent on those in the installation room.

It is therefore an object of the present invention to provide a plant cultivator and a method which overcomes the aforementioned disadvantages of known plant cultivators. In particular, it is an object of the present invention to provide a plant cultivator and a corresponding method which enables a largely autonomous cultivation of plants.

This object is achieved with the features of the independent claims. The dependent claims relate to further aspects of the invention.

According to a first aspect of the present invention, there is provided a plant cultivator for growing plants. The plant cultivator comprising: a closed housing having at least one cooling device to cool at least a predetermined area within the housing. The at least one cooling device is configured to recapture water transpired from the plants and / or evaporated water from a substrate (plant substrate) at the at least one cooled area and to reuse the plants or their roots.

As a result, the plant cultivator of the present invention ideally comes without externally guided active components / media / aggregates, only electrical energy must be supplied via a power cable.

The term "active components / media / aggregates guided to the outside" should be understood in this context to mean that all required media, components and units are safely located in or on the housing of the cultivator and no cables, hoses, pipes, etc. are loosely adjacent Aggregates, control systems and supply media lead. This is advantageous because the plant cultivator is so much easier relokierbar, a suitable site is easier to find, the risk of accidents is reduced and the complexity and thus the costs are lower.

The housing of the plant cultivator is arbitrarily scalable and adaptable in shape to the respective requirements.

Preferably, the plant cultivator has at least one intermediate floor (subdivision) which divides the housing into at least one upper and one lower zone (an upper and a lower zone) Area), each of the zones (areas) having at least one cooled area.

In other words, it is preferable to divide the plant cultivator's housing into several zones (areas).

The upper and lower zones can be understood as two control technically separate zones. The upper and lower zones may additionally have some form of adjustable air circulation to balance water between the individual plants (planters).

The cooling of a predetermined area by the cooling device may be both the cooling of a portion of the cooling device itself, as well as an area that does not belong to the cooling device.

It is preferred that the at least one area cooled by the cooling device is provided on at least one side wall and / or ceiling of the housing and / or an intermediate floor.

Thus, the cooling device can cool at least a portion of a side wall and / or a ceiling and / or an intermediate floor.

In this case, the cooling device and the cooled area may locally fall apart or collapse locally. For example, a cooling device mounted on a sidewall may cool the sidewall by contact in the area where the cooling device is attached to the sidewall.

Alternatively, the cooling device may be attached to a first location of the sidewall and cool the wall at a second location such that the cooled portion of the sidewall falls apart with the mounting location of the cooling device. For example, by cooling line (s), the cooling of the cooling device can be guided to certain areas of the side wall.

The cooling device may also be located anywhere that does not correspond to a location on the side wall and still cool a certain portion of the side wall. The cooling device can be located both inside and outside the plant cultivator.

The exemplary embodiments described in relation to the side wall apply equally to the ceiling of the housing and a possible intermediate floor.

The back wall, d. H. the wall of the housing opposite the door of the housing is generally referred to as a sidewall in the context of this invention. Ie. if spoken in this application of side wall, this includes the rear wall of the housing with.

Thus, a housing according to the present invention preferably consists of a ceiling (top), a bottom (bottom) and four side walls, wherein the four side walls preferably have at least one front, with for example a door or drawer, and a back.

It is preferred that the at least one cooling device and / or the (at least partially) cooled side wall (s) and / or the (at least partially) cooled ceiling of the housing and / or the (at least) cooled ( n) intermediate floor (floor) has a smooth surface for the effective recycling of the recondensed water.

The return is preferably carried out by utilizing gravity. Thus, no additional pumps, valves, hoses or tanks, etc. are necessary.

The at least one cooled portion of the plant cultivator may be located locally above the roots of the plant (s) and / or the plant substrate to facilitate recirculation of the recondensed water by utilizing gravity.

The housing is preferably a semi-hermetically sealed housing or a hermetically sealed housing. The term "semi-hermetically sealed housing" is to be understood in this context as a housing which is substantially impermeable at least for gases, but the housing may well have leakage to a certain extent. In particular, the term "semi-hermetically sealed housing" is to be understood as a housing which substantially prevents an exchange with the ambient air, at least so far that during a plant cultivation period, particularly preferably within 2 to 6 weeks, the loss of water due to water vapor leakage does not occur Supplying water into the housing is required. The water loss of a growing period can usually be absorbed by the storage capacity of the nutrient medium.

The cooling using the at least one cooling device can be achieved by evaporating a refrigerant, by absorption using a water-ammonia mixture in a hydrogen atmosphere or by thermoelectric effects (Peltier effect) can be achieved. These principles are known to those skilled in the refrigeration art and may be incorporated appropriately in the plant cultivator.

The term "recondensate" is to be understood in the context of the present invention as condensed under the dew point of humidity. In other words, the transpired in the gaseous state of the plants and evaporated from the nutrient medium water is converted by the cooling, preferably on a side wall and / or ceiling and / or false floor, in the liquid state. Thus, the water can be returned to the plants and the relative humidity in the housing interior to a value necessary for the plants are kept less than 100%. A certain positive vapor pressure difference is necessary so that the plants can transport water from the roots to the leaves. This vapor pressure difference is maintained by the recondensation of air humidity in the housing and is essential for nutrient transport in the plant.

For supplying water transpired from the plants and / or evaporated from a nutrient substrate (plant substrate), each of the zones may have at least one correspondingly cooled area (wall, eg sidewall, ceiling, intermediate floor). However, only selected zones can have a water recycling according to the invention. For example, there may be one or more zones in the housing in which water recycling is not desired or required.

Each of the zones in the housing may additionally have at least one illumination unit in order to promote or facilitate photosynthesis in the plants. The lighting unit may be, for example, an LED lighting unit. Lighting units suitable for plant breeding are known to the person skilled in the art and can be installed accordingly in the plant cultivator.

Preferably, lighting units with red and blue light are used.

The plant cultivator may comprise at least one baffle connected to the at least one cooled area and / or the at least one cooled sidewall and / or the cooled ceiling and / or the cooled intermediate floor and configured to deliver the recondensed water to the plants.

The guide element may be fixed or detachably connected to the side wall and / or the ceiling and / or the false floor.

The baffle may deliver the recondensed water from the at least one cooled area and / or the cooled sidewall and / or the cooled ceiling and / or the cooled shelf to the plants in a controlled manner. Preferably, the guide element is configured so that the recondensed water is supplied to the plants independently due to gravity.

The plant cultivator may further comprise a bottom of the casing and / or an intermediate bottom having a slope towards the at least one cooled portion to achieve distribution of the recondensed water.

In other words, the soil on which the plants are located may have a slope to better transport the recondensed water from one side, the side where the water is recondensed, to an opposite side. This is particularly advantageous if the water is recondensed on only one of the side walls and / or the rear wall of the housing.

Also advantageous is the use of a liquid-distributing substrate in which the plants are implanted. In addition, the inclination of the soil can further improve the liquid distribution.

The plant cultivator may comprise at least one plant box ("plant tray", "planting tray") interchangeably mounted in the plant cultivator. A plant box has the advantage that it is easily replaceable from the plant cultivator.

Preferably, the plant box may be fixed in the plant cultivator using at least one holding device (adjusting device). The holding device may be provided at the bottom of the housing and / or at the intermediate floor of the plant cultivator to receive the at least one plant box.

The holding device is preferably configured to generate a slope of the at least one plant box in the direction of the at least one cooled area. As already described above in connection with the inclined floor, a slope in the direction of the cooled area for the water distribution may be advantageous.

The above-mentioned guiding element is particularly preferred when using a plant box. Here, a possible distance to the cooled side or rear wall can be bridged. In other words, guiding elements can be targeted Supply of recondensed water to the plants.

Ie. If a plant box is provided in the cultivator, the guide element described above can alternatively also be attached to the plant box. By placing the plant box in a predetermined position, the baffle is associated with the at least one cooled area and / or the at least one cooled side wall and / or the cooled ceiling and / or the cooled intermediate floor, so that the recondensed water to the plants can be performed.

The plant cultivator may include at least one air circulation unit configured to generate air circulation in the plant cultivator. An example of an air circulation unit is a fan. The air circulation generated thereby can, on the one hand, ensure a uniform distribution of the moisture and, on the other hand, the amount of water which is fed to the individual plants or plant boxes via the recondensation can be controlled (balanced).

The plant cultivator may further comprise a CO ₂ fertilizer unit, for example, via a connection to the housing or a carbon dioxide storage or generating unit, for. B. a pressure bottle with liquid CO ₂ in the housing or other methods (microbiological decomposition of sugar by yeast bacteria, chemical reaction, combustion of hydrocarbons, etc.) is configured to supply the housing interior of the plant cultivator CO ₂ .

The plant cultivator may include a humidity sensor and / or a temperature sensor and / or a CO ₂ sensor.

The plant cultivator may further include a control unit, e.g. As a microcontroller or industrial PC or any electronic control, which is connected to the humidity sensor and / or the temperature sensor and / or the CO ₂ sensor and is configured based on the connected sensors, the humidity and / or temperature and / or to monitor the CO ₂ content inside the plant cultivator and / or automatically regulate to predetermined levels.

The plant cultivator may preferably include at least one substrate moisture measurement device configured to measure the moisture of the substrate in which the plants reside.

Preferably, at least one resistance sensor configured to measure, via the ohmic resistance, the moisture of the substrate in which the plants are located serves as substrate moisture measuring device.

Alternatively or in addition to the resistance sensor, the plant cultivator may have as substrate moisture measuring device at least one weight sensor configured to measure the weight of the substrate in which the plants are located. Thus it can be concluded indirectly from the weight to the moisture of the substrate.

However, the present invention is not limited to the previously described possibilities of a substrate moisture measuring device. Rather, the person skilled in the art further possibilities for determining the moisture of the substrate are known and can be used in the present invention. For example, capacitive methods, methods using microwaves, tensiometers, time domain transmission sensors (TDT) or thermal determination methods can also be used.

Alternatively or additionally, the plant cultivator may also include methods of plant moisture metering configured to determine the water content of the plant. As a plant moisture measuring device, for example, methods for measuring the Turgordrucks or similar methods known in the art can be used.

The plant cultivator may comprise another or the control unit already described above, connected to the substrate moisture meter and / or the plant moisture meter and configured to regulate the water supplied to the plants, wherein the regulation of the water supplied via a regulation of the temperature of the at least one cooled area and / or via a regulation of at least one air circulation unit.

The control unit can be different programs, such. Plant specific, store and use as directed by the user.

The plant cultivator preferably has exclusively connections to the power supply and / or to the supply of CO ₂ and / or to the connection of a control unit. Thus, the plant cultivator according to the invention ideally requires neither sewage nor fresh water connection or other external media.

According to another aspect of the present invention there is provided a method of growing plants in a plant cultivator, especially in a plant cultivator as described above. The method comprises the steps of: a) cooling at least a predetermined area of the plant cultivator to recondensate water transpired from the plants and / or evaporated from a substrate at the at least one cooled area; and b) supplying the recondensed water to the plants.

The present invention is also intended to cover the use of a plant cultivator according to the invention for the cultivation of plants, in particular "microgreens" and herbs.

In the context of the present invention, "microgreens" are vegetables and herbs which, after budding, already carry out photosynthesis and have from one cotyledon pair to several true leaves. These are used for example in the upscale kitchen for appearance and taste. Examples are peas, broccoli, red cabbage, mustard, garlic, basil, coriander etc. Microgreens are usually harvested 1 to 3 weeks after germination and the aerial part of the plant is consumed without the roots.

Thus, according to the present invention, an easy-to-use device for the kitchen, especially in the catering industry, for the automatic rearing of plants, especially microgreens and herbs, are provided.

The plants need little care according to the present invention and can therefore be reared without appropriate "know-how" regarding plant rearing.

The recondensation of the water according to the invention avoids water pouring and the preferred regulation of the parameters provides optimum conditions for growth.

The controlled circulation of the air additionally ensures an even distribution of the humidity or the temperature and thus a balanced distribution of the condensate (water).

The plant cultivator is insensitive to the ambient temperature and has preferably, except for a power connection and optionally a hose for the supply of CO ₂ , no external components. This leads to insensitivity to the damage of external parts, easier finding a suitable site, easier Relokieren, easier handling, minimized error rate and accident risk.

The plant cultivator of the present invention is also advantageous over the known cultivators in that it can preferably use smooth and easily cleanable surfaces in all relevant areas that are in contact with the atmosphere inside, which is not possible with complex multi-port cultivators. Ventilation with ambient air also increases the risk of pumping in, for example, fungal spores and bacteria into the housing interior with the intake air.

The plant cultivator can also be connected to the Internet and monitored and controlled from a distance. The controller can also be operated via an application (App) or website on the mobile phone, tablet, laptop, etc.

The plant cultivator can additionally have a cloud connection.

Furthermore, the plant cultivator may have a "freshness-keeping mode" so that the harvest-ripe plants, in particular "microgreens", stay fresh for a long time, since they can only be harvested for a certain period of time in order to meet the demands in the upscale gastronomy. It is advisable for this purpose, for example, to reduce the temperature to a lower value and / or to reduce the CO ₂ content accordingly to a minimum and / or to reduce the activity of the photosynthesis by lowering the illumination intensity and / or duration.

The plant cultivator may additionally have a germ pocket. This makes it possible to germinate seed boxes with seed under optimal conditions. Many plants are dark germs, so a space-saving compartment with optional lighting in the interior is an advantage.

In summary, the present invention provides a plant cultivator for growing plants.

Preferably, in a (semi) -hermetically closed housing a specific climate is generated, which is characterized by temperature, humidity, light and CO ₂ . The parameters for temperature, light, humidity and CO ₂ are preferably measured by sensors and controlled by a microcontroller.

The plants operate by CO ₂ in the air and the lighting with appropriate wavelength photosynthesis.

By transpiration, the plant or the nutrient medium (substrate) increases the humidity inside the housing. This moisture is recondensed on the wall or the ceiling or the intermediate floor and fed by gravity back to the roots of the plant. This takes up the recycled water again and can thus continue to grow without casting costs.

Due to the semi-hermetically sealed housing, no (or hardly any) moisture escapes to the outside and the once supplied water stored in the substrate circulates inside the box and is used again and again.

Similarly, the closed design of the plant cultivator allows the controlled delivery of CO ₂ . The control unit with microcontroller and other components are preferably mounted on a circuit board.

For example, planters (plant boxes) are initially filled with substrate and seeds and placed on different levels using false floors. Each level is lit from above with LED's or other bulbs. A single level embodiment is also conceivable.

The LEDs are preferably mounted on metal core boards and can be made to heat the overlying planter. Temperature, duration and intensity of the light irradiation, humidity or vapor pressure difference and CO ₂ content of the air are preferably measured with sensors and controlled by a microcontroller based on a set program.

By the CO ₂ in the air and the irradiation with light specific wavelengths the germinated plants operate photosynthesis. Through at least one cooled and smooth surface, the moist air recondenses on this surface and is returned to the plants with the help of gravity, ie without pumps or the like.

If the plants are in a ripe state (especially in gastronomy microgreens are only usable up to a certain growth stage), the plant cultivator can change the parameters so that the conditions in the box inhibit the further growth of the plants.

After the harvest, planting bowls are again infested with substrate and seeds, and a cycle starts again, as described above. The monitoring of the parameters can also be stored in the cloud and analyzed via a mobile device. So the user can let the box work independently and gets in case of problems via mobile devices.

For example, a layman put the planting bowls with substrate and seeds in the plant cultivator, pours them once and takes after appropriate time (depending on the type of plants different) the ripe plants from the plant cultivator. In the meantime, the plant cultivator can be monitored by the controller and, if desired, by a mobile device.

Hereinafter, the present invention will be explained in more detail with reference to embodiments and the figures.

Show it:

1 a schematic representation of a first exemplary embodiment of the plant cultivator according to the invention,

2 1 is a schematic representation of a second exemplary embodiment of the plant cultivator according to the invention with an additional compartment,

3 1 is a schematic representation of a third exemplary embodiment of the plant cultivator according to the invention with two planters in the same plane,

4 a schematic representation of a fourth exemplary embodiment of the plant cultivator according to the invention with three planters in a plane.

For the same components, the same reference numerals are used in the figures. In order to avoid repetition, components already described in relation to one embodiment are not described repeatedly in subsequent embodiments. Only the differences between the following embodiments and the previous embodiments will be described.

1 shows an arrangement according to an exemplary embodiment of the present invention. 1 shows a housing 10 a plant cultivator 1 ,

The housing 10 of the plant cultivator 1 is semi-hermetically sealed and consists of a door 11 , a side wall 12 , a blanket 13 and a floor 14 ,

The door 11 in this case preferably has a rubber seal (not shown) to the interior of the housing 10 at least semi-hermetically sealed to the outside. The door 11 therefore designed to semi-hermetically close the interior in a closed state and in an open state access to the interior of the plant cultivator 1 to allow.

The door 11 can also by other forms for closing the plant cultivator 1 be replaced. For example, the door could 11 be replaced by one or more drawers.

The side wall 12 is a cooled sidewall according to the exemplary embodiment 12 , In this embodiment, the cooling device is in the side wall 12 integrated. This is indicated by the circles which are intended to represent a section through the copper pipes of an evaporator of a compression refrigeration cycle (cooling device).

However, the present invention is by no means cooling the sidewall 12 limited. A cooled ceiling 13 or another sidewall of the enclosure, including the door 11 , fulfills the concept of the invention equally.

The cooling unit of the cooled side wall 12 can be anywhere on the sidewall 12 be provided. In the case of several separate zones, however, it is advantageous if all zones in which water recycling is to be achieved have such a cooling unit or should the cooling unit extend over all of these zones or can the zones be individually separated for balancing the recycled water, be controlled separately from each other.

As a cooling device, any known device for cooling is suitable. This can be in the sidewall 12 incorporated or be provided as a separate unit, for example, a separate cooling unit.

The ceiling 13 closes the case 10 of the plant cultivator 1 upwards and, as already described, may alternatively or additionally comprise a cooling device.

In the 1 shown exemplary embodiment also has two shelves 70 . 71 on. The shelves 70 . 71 divide the plant cultivator 1 in different independent zones, the number of shelves can be chosen arbitrarily.

As already described above, preferably each should be through an intermediate floor 70 . 71 defined zone have a standalone cooling device. Alternatively, a cooling device can also extend over the different zones, wherein the balancing of the recondensed water in this case can preferably take place via air circulation units which can be controlled separately from one another.

However, there may also be areas in the plant cultivator 1 in which no water return is desired. In these zones, therefore, no cooling devices must be present.

The plants are in the plant cultivator 1 in plant boxes 50 . 51 . 52 , preferably in a substrate or soil. The plant boxes 50 . 51 . 52 are however essential. Alternatively, the plants may also be directly, preferably in a substrate or soil, on the ground 14 or the intermediate floors 70 . 71 be planted. These can also be designed as pull-out drawers.

The exemplary embodiment according to 1 further shows guide elements 30 . 31 . 32 that help on the cooled sidewall 12 recondensed, transpired by the plants, water to the plants.

The guiding elements 30 . 31 . 32 are particularly advantageous as baffles with an additional nose formed at its free end.

Furthermore, the guiding elements 30 . 31 . 32 particularly advantageous if the in 1 shown plant boxes are used and this a certain distance from the side wall 12 exhibit. The guiding elements 30 . 31 . 32 but are also in other configurations of the plant cultivator 1 advantageous.

The plant cultivator 1 according to the exemplary embodiment of 1 has additional holding devices 60 . 61 . 62 . 63 . 64 . 65 on. The holding devices 60 . 61 . 62 . 63 . 64 . 65 are suitable, the plant boxes 50 . 51 . 52 and may also be designed as scales capable of detecting the weight of individual planters.

Preferably, the holding devices 60 . 61 . 62 . 63 . 64 . 65 as in 1 shown formed so that this a slope to the cooled side wall 12 define.

In other words, the holding devices 60 . 62 . 64 are each formed higher than the holding devices 61 . 63 . 65 , Thus, a tilt from the cooled sidewall 12 towards the opposite side wall, in this case the door 11 , be achieved. This, in turn, promotes water distribution from that on the sidewall 12 recondensed water to the opposite side.

The embodiment of the holding devices 60 . 61 . 62 . 63 . 64 . 65 is not intended to the holding devices shown here 60 . 61 . 62 . 63 . 64 . 65 be limited. For example, the holding devices 60 . 61 . 62 . 63 . 64 . 65 each be formed in one piece or multiple parts.

Alternative to the holding devices 60 . 61 . 62 . 63 . 64 . 65 , can also be a sloping ground 14 or inclined shelves 70 . 71 used to achieve the same effect. This embodiment is particularly preferred when no plant boxes 50 . 51 . 52 be used. But also with plant boxes 50 . 51 . 52 may be a use of a sloping floor 14 or inclined shelves 70 . 71 be used.

The plant cultivator according to 1 further shows LED lighting units 20 . 21 . 22 and fans 40 . 41 . 42 ,

The LED lighting units 20 . 21 . 22 are preferably used to allow photosynthesis in the plants. The LED lighting units 20 . 21 . 22 are each on the ceiling 13 or on the shelves 70 . 71 attached above the plants to be illuminated.

The number and arrangement of LED lighting units 20 . 21 . 22 is arbitrary. Preferably, the LED lighting units 20 . 21 . 22 However, at one point of the housing 10 attached to the no cooling is done so as not to disturb them.

The LED lighting units 20 . 21 . 22 can be used as heat sources in addition to their light. In the exemplary embodiment shown here, the LED lighting units 21 . 22 each above the intermediate floors 70 . 71 located by the plants of the LED lighting units 21 . 22 heat generated heat. This can be beneficial in the germination of certain varieties ("warm germ").

The fans 40 . 41 . 42 can generate air circulation in the various zones, which can promote the growth of plants and the transpired water on the side wall 12 is introduced. The air circulation also ensures a more even heat distribution.

Thus, by varying the speed of the fans 40 . 41 . 42 also influence on the amount of recycled water are taken. In particular, by a directed air flow, indicated by the arrows in 1 , such regulation of recycled water can be achieved. Here, the direction of the arrows shown is to be understood only as an example - a reversed or rotated by 90 ° orientation of the fans fulfills the same purpose.

In other words, by a directed air flow passing through the fans 40 . 41 . 42 is generated, air can be targeted to the cooled side wall 12 be guided. This allows the amount of transpired water on the sidewall 12 influence.

The plant cultivator 1 The present invention preferably further comprises a CO ₂ fertilizer unit (not shown).

The CO ₂ fertilizer unit is connected via a port (not shown) to the housing 10 connected and leads to the interior of the housing CO ₂ .

The plant cultivator 1 The present invention may further comprise various sensors (not shown), for example a humidity sensor and / or a temperature sensor and / or a CO ₂ sensor.

The sensors are preferably monitored by a control unit (not shown) based on humidity and / or temperature and / or CO ₂ content inside the plant cultivator 1 to automatically adjust the aforementioned parameters to preset values.

The plant cultivator 1 The present invention may further include one or more resistance sensors (not shown) and / or one or more weight sensors (not shown).

The resistance sensor can measure the ohmic resistance in the substrate or the earth. Since the ohmic resistance or the conductivity of the substrate or the earth depends on the moisture of the substrate, the moisture of the substrate or the earth can be determined.

The weight sensor can determine the weight of the substrate or the earth. Since the weight changes depending on the moisture contained in the substrate, the weight sensor can also be used to indirectly determine the moisture content of the substrate.

The measured data of the resistance sensor and / or the weight sensor can be evaluated by the above-mentioned control unit (microcontroller). In addition, the microcontroller can automatically control the temperature (even in partial areas) of the cooled side wall 12 and / or via an automatic control of the fans 40 . 41 . 42 to achieve a regulation of the recycled water quantity.

2 shows a second exemplary embodiment of a plant cultivator according to the invention 2 , In particular shows 2 a housing 10 a plant cultivator 2 with separate compartment 80 , The field of expertise 80 For example, it may have refrigeration technology, a CO ₂ storage and / or generating device, regulation and electrical engineering.

This embodiment enables a particularly compact design of the plant cultivator 2 ,

3 shows a third exemplary embodiment of a plant cultivator according to the invention 3 , In particular shows 3 in contrast to the embodiments described above, a structure of the plant cultivator with two planters 50 . 51 in the same plane, an integrated CO ₂ supply 90 over z. As a commercial carbonated bottle in a size, for example, for private kitchens.

The CO ₂ supply 90 preferably has a front replaceable CO ₂ pressure bottle.

4 shows a fourth exemplary embodiment of a plant cultivator according to the invention 4 , According to the fourth embodiment, the plant cultivator 4 three planters in one plane. 4 shows a housing 10 a plant cultivator 4 with compression chiller 100 , Valves 120 . 121 . 122 for controlling the subregions 110 . 111 . 112 the partially coolable rear wall (rear side wall).

4 also shows a minor that a compressor 100 the refrigeration circuit with the heat-emitting condenser 101 having.

Furthermore, an external CO ₂ supply via in catering and dispensing standard CO ₂ bottle 91 shown. The carbon dioxide supply is an adjacent carbon dioxide pressure bottle 91 that have a connection 92 is connected to the housing with this.

A regulation 140 (including pulse width regulation of the fans 40 . 41 . 42 and evaluation of recorded sensors, measurement of the individual weights of the planters, temperature, CO ₂ content and humidity in the interior of the housing), with connected CO ₂ / humidity / temperature / vapor pressure difference sensor 150 as well as substrate moisture measuring devices (balance, ohmic sensor, capacitive sensor, etc.) 160 . 161 . 162 . 163 . 164 . 165 ,

While the present invention has been described and illustrated with reference to its preferred embodiment, it will be apparent to those skilled in the art that various modifications and changes may be made thereto without departing from the scope of the invention. In this way, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Furthermore, individual units may perform one or more functions defined in the claims. Previously described features of the exemplary embodiment may be combined as desired, i. H. the features of a particular exemplary embodiment are not limited to this embodiment.

Claims (12)

Plant Cultivator ( 1 ) for growing plants, the plant cultivator ( 1 ): a closed housing ( 10 ) with at least one cooling device to at least a predetermined area within the housing ( 10 ) to cool; wherein the at least one cooling device is configured to recapture water transpired from the plants and / or evaporated from a substrate at the at least one cooled region and to reuse the plants. Plant Cultivator ( 1 ) according to claim 1, further comprising: at least one intermediate floor ( 70 . 71 ), the housing ( 10 ) is subdivided into at least one upper and one lower zone, each of the zones having at least one cooled area. A plant cultivator according to claim 1 or 2, wherein the at least one area cooled by the cooling device is located on at least one side wall ( 12 ) and / or a ceiling ( 13 ) of the housing ( 10 ) and / or an intermediate floor ( 70 . 71 ) is provided. Plant cultivator according to one of claims 1 to 3, further comprising: at least one air circulation unit ( 40 . 41 . 42 ) configured to recirculate air in the plant cultivator ( 1 ) and / or a CO ₂ fertilizer unit, which via a connection on the housing ( 10 ) or a carbon dioxide storage or generating unit is configured in or on the housing, the plant cultivator ( 1 ) To supply CO ₂ . Plant Cultivator ( 1 ) according to one of claims 1 to 4, further comprising: a moisture sensor and / or a temperature sensor and / or a CO ₂ sensor and a control unit which is connected to the humidity sensor and / or the temperature sensor and / or the CO ₂ sensor and is configured, based on the connected sensors, the moisture and / or the temperature and / or the CO ₂ content in the interior of the plant cultivator ( 1 ) and / or automatically regulate to predetermined values. Plant Cultivator ( 1 ) according to one of claims 1 to 5, further comprising: at least one guide element ( 30 . 31 . 32 ) with the at least one cooled area and / or the at least one cooled side wall ( 12 ) and / or the at least one cooled ceiling ( 13 ) and / or the at least one cooled intermediate bottom ( 70 . 71 ) and configured to deliver the recondensed water to the plants. Plant Cultivator ( 1 ) according to any one of claims 1 to 6, further comprising: at least one plant box ( 50 ) exchangeable in the plant cultivator ( 1 ) is mounted and preferably at least one holding device ( 60 . 61 . 62 . 63 . 64 . 65 ), on the ground ( 14 ) of the housing ( 10 ) and / or at the intermediate floor ( 70 . 71 ) of the plant cultivator ( 1 ) is provided to the at least one plant box ( 50 ), wherein the holding device ( 60 . 61 . 62 . 63 . 64 . 65 ) is preferably configured, a slope of the at least one plant box ( 50 ) in the direction of the at least one cooled region. Plant Cultivator ( 1 ) according to one of claims 1 to 7, further comprising: at least one substrate moisture measuring device configured to measure the moisture of the substrate in which the plants are located, a control unit which is connected to the substrate moisture measuring device and is configured to supply the plants Regulation of the water supplied via a regulation of the temperature of the at least one cooled area and / or via a regulation of the at least one air circulation unit ( 40 . 41 . 42 ) he follows. Plant Cultivator ( 1 ) according to any one of claims 1 to 8, wherein the plant cultivator ( 1 ) exclusively has connections to the power supply and / or to the supply of CO ₂ . Plant Cultivator ( 1 ) according to one of claims 1 to 9, wherein the soil ( 14 ) of the housing ( 10 ) and / or the intermediate floor ( 70 . 71 ), has a slope in the direction of the at least one cooled region in order to achieve a distribution of the recondensed water. Plant Cultivator ( 1 ) according to any one of claims 1 to 10, wherein the at least one cooled region is located locally above the roots of the plant and / or the plant substrate to allow for recirculation of the recondensed water by utilizing gravitation. Method for growing plants in a plant cultivator, in particular in a plant cultivator ( 1 ) according to any one of claims 1 to 11, wherein the method comprises the steps of: a) cooling at least a predetermined area of the plant cultivator to recondensate water transpired from the plants and / or evaporated from the substrate at the at least one area; and b) supplying the recondensed water to the plants.

Images