WO2018046032A1 - Plant habitat - Google Patents

Abstract

The invention relates to a plant habitat which allows a barrier-free all-round view or a 360° view of a plant provided in the habitat. The plant habitat according to the invention comprises a transparent housing element (2) which forms a cavity (2.1) and which has at least one transparent electrically conductive coating for transmitting electric energy, at least one lighting means (5) which is directed towards the cavity (2.1) and which is electrically contacted to the transparent electrically conductive coating, an energy supply device for providing electric energy to the transparent electrically conductive coating, means for preventing condensation on the transparent housing element (2), and at least one housing cover (4.1; 4.2) for covering the cavity (2.1) in a fluid-tight manner.

Description

 plant habitat

The invention relates to a plant habitat which makes possible a barrier-free all-round viewing or a 360 ° view of a plant present in the habitat.

For the growth of indoor plants or environments unfavorable to plant growth, natural conditions can be mimicked by technical means such as lighting, temperature control and ventilation. In order to maintain growth-friendly conditions, plants are planted in closed systems, such as in transparent glass vessels or glass casings, where they can grow largely untouched by external influences. Naturally, the plants are illuminated from above, whereby it is necessary that the electrical energy supply in the form of electrical lines must also be supplied from above, through the housing or via a housing outside. However, this has the disadvantage that the constructive clearance above the housing or the degree of freedom for viewing the interior of the housing is adversely affected. In particular, in case of housing bodies which allow a Rundumbetrachtung or case housings with a particularly aesthetic design interfere with the outside supplied electrical lines a view of the viewer to the housing interior.

Furthermore, there is the problem that due to temperature and humidity differences between the environment and the interior of the housing to condensation on the housing wall, whereby the visibility of the housing interior is impaired. In addition, combina-

| Confirmation copy | Condensation is an undesirable growth of bacteria and fungi.

The object underlying the present invention is now to propose a plant habitat with which the growth conditions required for a plant can be provided and a barrier-free all-round consideration of a plant present in the habitat is made possible.

According to the invention the object is achieved by a plant habitat with the features of claim 1. Advantageous embodiments and further developments of the invention can be realized with features described in the subordinate claims.

The plant habitat according to the invention comprises a transparent housing element forming a cavity which has at least one transparent electrically conductive coating for transmitting electrical energy. In this case, the transparent housing element and the cavity may preferably be cylindrically shaped and have at least one opening. The cavity serves to accommodate a plant and can be dimensioned accordingly. Furthermore, the plant habitat comprises at least one illuminant directed onto the cavity, which is electrically contacted with the transparent electrically conductive coating, and a power supply device for providing electrical energy to the transparent electrically conductive coating. Conveniently, the power supply device is electrically contacted with the transparent electrically conductive coating. The plant habitat according to the invention also comprises means for avoiding condensation on the transparent housing element and at least one housing cover for fluid-tight covering of the cavity.

The transparent electrically conductive coating is an oxide layer (English Transparent Conducting Oxide, TCO), which is formed from electrically conductive materials with a relatively low absorption of electromagnetic waves in the visible light range. Preferably, the transparent electrically conductive coating may be formed with at least one transparent electrically conductive oxide, which is selected from a group consisting of: indium tin oxide, fluorine tin oxide, aluminum zinc oxide and antimony tin oxide. The provision of the transparent electrically conductive coating on the transparent housing element can be carried out by known methods, such as PVD or CVD. Expediently, the layer thickness and / or layer width of the transparent electrically conductive coating is chosen such that the electrical energy required to operate the luminous means can be provided.

According to one embodiment variant of the plant habitat according to the invention, the transparent electrically conductive coating may be formed at least in regions on a side of the surface of the transparent housing element facing the cavity. Conveniently, the coating has an interruption to ensure a dipole. In a further variant it can be provided that a first transparent electrically conductive coating is formed on a side facing the cavity of the surface of the transparent housing element, wherein a second transparent electrically conductive coating is formed on an outer side facing away from the cavity of the surface of the transparent housing element is.

By using a transparent electrically conductive coating for the transmission of electrical energy, the plant habitat according to the invention makes it possible to illuminate a plant present in the cavity without electrical connection cables obstructing a viewer's view of the interior of the plant habitat. The barrier-free view therefore makes it possible to have a 360 ° view, so that the plant habitat can advantageously be placed centrally in a room. This proves to be particularly advantageous at exhibitions, since the viewer from almost any position in the room has a barrier-free view of the interior of the plant habitat and thus can obtain a complete impression of the spatial structure of existing in the plant habitat plant. Expediently, the energy supply device can be arranged on a side of the transparent housing element which is opposite to the luminous means, so that the widest possible viewing angle is achieved between the luminous means and the energy supply device. Basically, with regard to the arrangement of the Illuminant in the cavity, however, no restriction, provided that it is ensured that the lamp is electrically contacted with the transparent electrically conductive coating.

The transparent housing element is a housing with at least one opening through which the plant can be introduced into the cavity. In the simplest embodiment, therefore, the cavity serves to receive the plant.

The energy supply device for supplying electrical energy to the transparent electrically conductive coating can be formed with a mains voltage-fed transformer, which transforms the mains voltage to a voltage required for operation of the luminous means. It can also be provided a variant in which the light source and other existing in the plant habitat electrical consumers are tuned to a mains voltage of, for example, 230 V, so that no transformation is required. For the purposes of the invention, a cable connected to the mains voltage is then to be understood as a power supply device.

In a further advantageous embodiment variant of the plant habitat according to the invention, the transparent housing element can be enclosed or covered in a fluid-tight manner between an upper and a lower housing cover, wherein the luminous means in the upper housing cover and the energy supply device are arranged in the lower housing cover. In this embodiment variant, the transparent housing element may have two end openings in the cavity, wherein the openings are closed fluid-tight by the upper housing cover and the lower housing cover. For a corresponding fluid tightness, a seal in the form of an O-ring or a lamellar seal can be provided.

According to a further advantageous embodiment variant, the plant habitat according to the invention can have a temperature control device arranged in the at least one housing cover for tempering the cavity. Advantageously, this can set a temperature necessary for plant growth. In addition, can the tempering device, which is set up for heating and cooling, be used to counteract fogging of the transparent housing element. Thus, the temperature control device is a means for avoiding condensation on the transparent housing element. The simplest possible embodiment of the temperature control device is realized with a Peltier element. Conveniently, the temperature control device can be contacted with the transparent electrically conductive coating for the supply of electrical energy. According to an advantageous development, the tempering device can also have a control device for controlling plant-specific temperature profiles, for example to simulate day-night cycles. It is also conceivable to store climate profiles for different plant species, wherein a growth-favorable climate can be set from a combination of temperature and ambient humidity.

According to a preferred embodiment variant of the plant habitat according to the invention, the means for avoiding condensation on the transparent housing element may be an air flow provided with at least one fan in the cavity, the ventilator being integrated in the at least one housing cover. By providing an air flow in the cavity, the risk of condensation on the inner wall of the transparent housing element is reduced, so that a visual impairment is prevented by the air flow. In addition, undesirable bacterial and / or fungal growth is reduced by a suitable air flow. Conveniently, the airflow generated by the fan may be directed to the cavity facing surface of the transparent housing member. Furthermore, in the at least one housing cover, in which the fan is arranged, a plurality of air slots or apertures may be provided, which predetermine the direction of air flow, so that the air flow can be directed to different areas in the cavity.

Furthermore, it can be provided in this embodiment that in both, the upper housing cover and the lower housing cover, a fan is arranged. In the event that a fan and the power supply device are arranged on opposite sides of the transparent housing element, it can be provided that the valve tor is electrically contacted with the transparent electrically conductive coating to be supplied with electrical energy. With regard to the technical design of the fan, there are no restrictions. For example, the fan can be designed as a radial or axial fan. Preferably, a fan should be used, which has a compact design as possible according to its design and enables low-noise operation.

An additional or alternative means of preventing condensation on the transparent housing member may be an anti-fog coating formed on the cavity-facing surface of the transparent housing member. Such an anti-fog coating can be formed, for example, with embedded in a polymer film silicon nanoparticles. Furthermore, it can also be provided that the entire surface of the transparent housing element has an anti-fog coating. Advantageously, the use of an anti-fog coating is combined with further means for preventing condensation on the transparent housing member, such as providing an air flow in the cavity, to prevent visual deterioration due to condensation.

According to a further advantageous development of the plant habit according to the invention, the transparent housing element may be double-walled, with an intermediate space being formed between an inner wall and an outer wall. By this embodiment, another means for preventing condensation on the transparent housing member is provided because the gap forms a temperature barrier between the cavity and the external environment. Advantageously, the gap may be evacuated. In a further embodiment variant, provision may be made for a gas, preferably a heated gas, to be present in the intermediate space. A heating of the gas can be achieved, for example, by the tempering device, which according to this embodiment has a connection with the intermediate space.

Another means for avoiding condensation on the transparent housing member may be to adhere the surface of the transparent housing member by providing eclectic energy the transparent electrically conductive coating is heated. In this case, the transparent electrically conductive coating can be used as a resistance heater.

The plant habitat according to the invention is not limited to use of only one of the listed means for preventing condensation on the transparent housing element. Rather, a combination of the stated means for preventing condensation on the transparent housing element should be used in order to ensure the best possible viewing security of the interior of the plant habitat.

According to an advantageous development of the plant habitat according to the invention, the at least one housing cover may have openings which allow a gas exchange of the interior of the plant habitat with the environment. Preferably, the apertures may comprise a membrane which can retain liquid and / or be selective to certain gases. The type and amount of gas exchange can be adjusted by the type of membrane and the size of the exchange surface. Thus, the size of the surface for gas exchange can also be varied with diaphragms, which are attached according to a development of the openings. Alternatively or additionally, a fan for the intake of fresh air can be used.

Furthermore, the at least one housing cover may have a cavity for receiving a plant substrate, so that the plant is held by the housing cover. This makes it possible in a simple manner to assemble the transparent housing element and the housing cover, without the plant substrate, which may be, for example, earth, lava earth, clay granules, pumice stone or zeolite, reaching the transparent housing element.

To supply liquid to a plant, the at least one housing cover may have a reservoir for liquid. In this case, the reservoir can advantageously be connected to the cavity in which the plant substrate is contained. Furthermore, it may be provided that a swellable gel is used for the liquid supply, which delivers liquid as needed. This ensures that only defined amounts of liquid get into the substrate and liquid does not swell from the reservoir. pen, which is advantageous in particular in the case of a suspended support of the plant habit. Preferably, the reservoir is formed with a valve, can be supplied via the liquid from the outside.

As light sources LED, OLED, low-voltage fluorescent lamps or halogen lamps can be used. Particularly preferably, the light source can be formed with a plurality of LEDs or OLEDs which emit a light spectrum required for plant growth. LED and / or OLED prove to be particularly space-saving and can be arranged directly on the surface or integrated into the surface of the transparent housing element. The transparent housing element is preferably formed from glass. According to further embodiments, transparent plastic materials such as PMMA can be used for the transparent housing element.

According to a preferred embodiment variant, the plant habitat according to the invention can be designed as a closed system, without it being necessary to continuously supply substances from outside. In this embodiment, a fluid-tight or gas-tight closure of the cavity is provided. The plant habitat is once equipped with liquid, plant substrate and possibly additional nutrients and then sealed. Lighting, temperature control and the air flow are adjusted in such a way that a uniform liquid circulation is established inside the habitat. Advantageously, a particularly low-maintenance plant habitat can be provided, in which a supply of substances such as water, nutrients or atmospheric oxygen is required only in relatively wide intervals.

A further advantageous development of the Pflanzenha- bitats invention provides the use of capillary structures for liquid recycling in the plant substrate or in the liquid reservoir. The capillary structures preferably made of glass fibers may preferably be in

Be formed portion of the lower end face of the transparent housing member and having a connection to the liquid reservoir and / or a connection to the cavity for receiving a plant substrate. Advantageously, the capillary structures are formed in a region in a condensation sink is formed. The condensate sink can be an area where condensation collects by design. However, it can also be provided that the condensate sinks is provided artificially, in which in a non-visible from the outside area, preferably in the lower housing cover or at the transition from the transparent housing element into the lower housing cover, a lower temperature is maintained compared to the cavity temperature. For example, the tempering device can be used for a temperature difference in the condensate sink. Preferably, the condensate sink is formed with a cavity for receiving condensed liquid.

As mounting plants, which are particularly suitable for growth in the plant habitat according to the invention in a closed system, in particular Microsorum pteropus, Anubias bateri var. Nana, Pilea microphylla, Rizzia fluitans. be identified.

A holder of the plant habit according to the invention can be realized suspended or with a substructure, for example in the form of a stand. Advantageously, the plant habitat according to the invention can also be used as a luminaire or lamp, the light coupled out of the plant habitat by the luminous means being used for ambient illumination.

With reference to the following figure, the invention will be explained in more detail by way of example.

1 shows a schematic sectional view of an embodiment of the plant habitat according to the invention

FIG. 2 shows a schematic sectional view of a further embodiment of the plant habitat according to the invention Recurring features are identified in the figures with the same reference numerals.

1 shows a schematic sectional view of an embodiment of the plant habitat 1 according to the invention. The reference numeral 2 designates a transparent housing element forming a cavity 2.1, which in the example shown is a rotationally symmetrical glass body with frontal openings. The cavity 2.1 formed by the transparent housing element 2 serves for the arrangement or as a growth space for a plant. In the example shown, a representation of the plant was omitted for better illustration of the technical features. The surface of the transparent housing element 1 is formed by the outer surface 3.1 and the inner surface 3.2, which faces the cavity 2.1. According to the invention, at least one of the surfaces 3.1 or 3.2 has a transparent electrically conductive coating for transmitting electrical energy. According to the embodiment shown, both surfaces 3.1 and 3.2 have a transparent electrically conductive coating for transmitting electrical energy in order to form a two-terminal pole. As a transparent electrically conductive coating is, for example, an indium-tin oxide, a fluorine-tin oxide, an aluminum-zinc oxide or an antimony-tin-oxide coating in question.

Furthermore, plant habitat 1 according to the invention comprises, in the example shown, an upper housing cover 4.1 and a lower housing cover 4.2, which seal the transparent housing element 2 in a fluid-tight manner at the end openings or cavity 2.1. The lower housing cover 4.2 serves as a holder for the plant habitat. 1

The reference numeral 5, a einge- in the upper housing cover 4.1 encompassed luminous means is in, which is I ^'s in the example shown a LED array having a plurality of LEDs that emit a required for a plant growth light spectrum. Advantageously, the LED array can have an LED control with which the movement of the sun can be simulated. According to the invention, the luminous means 5 is provided with the transparent electrically conductive coating formed on the surface 3.1 and 3.2. electrically contacted. A supply of electrical energy is ensured with a power supply device (not shown) arranged in the lower housing cover 4.2, which supplies electrical energy to the transparent electrically conductive coating. Conveniently, the power supply device is electrically contacted with the transparent electrically conductive coating. In this case, the electrical contacting can be provided with soldering points on the surfaces 3.1 or 3.2, preferably in a region not visible from the outside, for example on the end faces. Preferably, the power supply device can be a transformer fed with mains voltage 6, which transforms the mains voltage 6 to a voltage required for operation of the lighting device 5. The transparent electrically conductive coatings allow a transmission of electrical energy, invisible to the human eye, so that the light source 5 can be operated without having to use the visual obstructing cable.

Furthermore, the plant habitat 1 according to the invention comprises means for avoiding condensation on the transparent housing element 2. A first means for avoiding condensation is realized with a fan 7 arranged in the upper housing cover 4.1, which provides an air flow in the cavity 2.1. In this case, an air flow generated by the fan 7 is directed through outlet openings 8, which are formed in the upper housing cover 4.1, directly to the surface 3.2 and thus prevents condensation of moisture on the surface 3.2. For supplying electrical energy, the fan 7 is electrically contacted with the transparent electrically conductive ones formed on the surfaces 3.1 and 3.2. The electrical contacts can be provided, for example, in each case with soldering points formed on the upper end face of the transparent housing element 2.

Furthermore, the inner surface 3.2 is provided with a transparent anti-fog coating, which is formed in the example embedded in a polymer film silicon nanoparticles. The anti-fog coating thus constitutes a further means for avoiding condensation on the transparent housing element 2. According to further advantageous embodiments, further means for avoiding condensation on the transparent housing element 2 can be used or combined. Thus, a temperature control device can be arranged in the lower housing element 4.2 or in the upper housing element 4.1, with which the cavity 2.1 and in particular the air flow generated by the fan 7 can be heated so that no condensation takes place on the surface 3.2. Furthermore, there is also the possibility of a double-walled embodiment of the transparent housing element 2 with an evacuated or optionally filled with heated gas intermediate layer. It is also conceivable to heat the surfaces 3.1 and 3.2 via the transparent electrically conductive coatings, wherein a correspondingly required electrical energy is provided to the electrically conductive coatings.

The reference numeral 9 designates a cavity formed in the lower housing cover 4.2 for receiving a plant substrate, such as lava earth. Below the cavity 9 is followed by a liquid reservoir 10, which can be filled with a valve (not shown) from the outside via the lower housing cover 4.2. The liquid reservoir 10 may contain an absorbent substance, such as a gel, which stores liquid and dispenses it as needed.

FIG. 2 shows a schematic sectional illustration of a further exemplary embodiment of the plant habitat 1 according to the invention, in which the plant habitat 1 is held suspended from the mains voltage cable 6 in contrast to the stationary embodiment shown in FIG. The

Mains voltage cable 6 terminates in a cable guide 6.1, wherein the mains voltage ^' before being provided to the transparent electrically conductive coatings which are formed in each case on the outer surface 3.1 and the inner surface 3.2 in accordance with the embodiment shown in Figure 1, with a (not shown) power supply device according to the power consumption of the light source 5 and the fan 7 is transformed.

As in FIG. 1, in the embodiment shown in FIG. 2, the fan 7 and the openings 8 are provided for directing the fan 7 Asked air flow in the upper housing cover 4.1 arranged.

The cavity 9 for a plant substrate and a liquid reservoir 10 are arranged in a holder 13, wherein the holder 13 is screwed or clamped in a groove 12 formed in the transparent housing element 2. In this case, the liquid reservoir 10 via a valve (not shown) can be filled from the outside, without the holder 13 must be removed. The lower housing cover 4.2 is held by several magnets or is clamped. Preferably, the lower housing cover 4.2 and the bracket 13 are coupled together.

According to an advantageous embodiment variant of the embodiment of the plant habitat 1 according to the invention shown in FIG. 2, a temperature control device for controlling the temperature of the cavity 2.1 can be arranged in the lower housing cover 4.2, wherein the temperature control device is electrically contacted with the transparent electrically conductive coatings formed on the surfaces 3.1 and 3.2. to be supplied with electrical energy.

The interruption 11 is intended to illustrate, by way of example, that the plant habitat 1 according to the invention can be embodied in different lengths and is not limited to the size ratio shown in FIG. Thus, the interruption 11 is not an actual interruption nor a two-part design of the transparent housing member 2.

Claims

Plant habitat (1), comprising,

a transparent housing element (2) which forms a cavity (2.1) and has at least one transparent electrically conductive coating for transmitting electrical energy,

at least one illuminant (5) directed onto the cavity (2.1), which is electrically contacted with the transparent electrically conductive coating, a power supply device for providing electrical energy to the transparent electrically conductive coating, means for avoiding condensation on the transparent housing element (2) , and at least one housing cover (4.1; 4.2) for fluid-tight covering of the cavity (2.1).

Plant habitat (1) according to Claim 1, characterized in that the energy supply device is arranged on a side of the transparent housing element (2) which is opposite the luminous means (5).

Plant habitat (1) according to one of claims 1 or 2, characterized in that the transparent housing element (2) between an upper housing cover (4.1) and a lower housing cover (4.2) is enclosed in a fluid-tight manner, wherein the lighting means (5) in the upper housing cover (4.1) and the power supply device in the lower housing cover (4.2) are arranged.

Plant habitat (1) according to any one of claims 1 to 3, characterized in that the transparent electrically conductive coating at least partially on a the cavity (2.1) facing side (3.2) of the surface of the transparent housing element (2) is formed.

Plant habitat (1) according to one of claims 1 to 4, characterized in that a first transparent electrically conductive Layer on a cavity (2.1) facing side (3.2) of the surface of the transparent housing element (2) is formed, wherein a second transparent electrically conductive coating on an outer side facing away from the cavity (2.1) (3.1) of the surface of the transparent housing element ( 2) is formed.

Plant habitat (1) according to one of claims 1 to 5, characterized in that the transparent electrically conductive coating is formed with at least one transparent electrically conductive oxide, which is selected from a group consisting of: indium tin oxide, fluorine tin Oxide, aluminum-zinc-oxide and antimony-tin-oxide.

Plant habitat (1) according to one of claims 1 to 6, characterized in that the means for preventing condensation on the transparent housing element (2) is an air flow provided with at least one fan (7) in the cavity (2.1), the fan (7) is integrated in the at least one housing cover (4.1; 4.2).

Plant habitat (1) according to claim 7, characterized in that the fan (7) is electrically contacted with the transparent electrically conductive coating.

Plant habitat (1) according to one of claims 7 or 8, characterized in that the air flow is directed to the cavity (2.1) facing surface (3.2) of the transparent housing element (2).

Plant habitat (1) according to one of claims 1 to 9, characterized in that the means for preventing condensation on the transparent housing element (2) is an anti-fog coating, which on the cavity (2.1) facing surface (3.2) of the transparent housing element (2) is formed.

Plant habitat (1) according to one of claims 1 to 10, characterized in that the transparent housing element (2) is double-walled is formed dig, wherein between an inner wall and an outer wall, a gap is formed.

12. plant habitat (1) according to claim 11, characterized in that in the intermediate space a gas, preferably a heated gas is present.

13. plant habitat (1) according to one of claims 1 to 12, characterized in that the surface (3.1, 3.2) of the transparent housing element (2) is heatable by providing eclectic energy to the transparent electrically conductive coating.

14. plant habitat (1) according to one of claims 1 to 13, characterized in that the at least one housing cover (4.1, 4.2) has openings that allow a gas exchange of the interior of the Planthabitathabitats (1) with the environment.

15. plant habitat (1) according to claim 14, characterized in that the openings have a membrane which retains liquid and / or is selective for gases.

16. plant habitat (1) according to one of claims 1 to 15, characterized in that the at least one housing cover (4.1, 4.2) has a cavity (9) for receiving a plant substrate.

17. plant habitat (1) according to one of claims 1 to 16, characterized in that the at least one housing cover has a reservoir (10) for liquid.

18. plant habitat (1) according to one of claims 1 to 17, characterized in that the lighting means (5) is formed with a plurality of LED or OLED, which emit a required for plant growth light spectrum.

19. plant habitat (1) according to one of claims 1 to 18, characterized in that the transparent housing element (2) is formed of glass.

20. plant habitat (1) according to one of claims 1 to 19, characterized in that the at least one housing cover (4.1; 4.2) has a tempering device for controlling the temperature of the cavity (2.1).