WO2022174855A1 - Phyto-conditioning device - Google Patents

Abstract

The invention relates to a phyto-conditioning device (8), having a panel body (1), an LED light source (3), a fan (4), and an energy connection line (5), wherein the panel body (1) has a panel upper face (1.1), a panel lower face (1.2), a panel end face (1.3), a panel rear face, and two panel side pieces, and the panel body has a flat basic shape and is designed to be arranged in a cabinet (2). The LED light source (3) is arranged in or on the panel body (1), and a light outlet surface of the LED light source is arranged on the panel lower face (1.2). The fan (4) is driven by an electric motor and is designed to provide an airflow between the panel lower face (1.2) and the panel upper face (1.1) or to circulate air on the panel lower face (1.2) or on the panel upper face (1.1), and the energy connection line (5) is arranged in the panel body (1) and is designed to provide energy to the LED light source (3) and the fan (4).

Description

PHYTOCONDITIONING DEVICE

The invention relates to a phytoconditioning device for influencing vegetation conditions for plants, preferably indoors, and to a phytoconditioning arrangement.

Different solutions for devices for artificially controlling the environmental conditions in the botanical field are known from the prior art. These are usually designed as a closed plant-breeding cabinet or greenhouse. In it, the environmental conditions for growing the plants can be controlled in a targeted manner. The controlled conditions include air supply, light intensity, light spectrum, watering and some other conditions. It is known to affect the metabolism, growth and life cycle of a plant by controlling conditions. This is of particular benefit when cultivating crops and ornamental plants. The solutions envisage special devices in the form of greenhouses or plant-growing cabinets. The disadvantage is that these have to be set up in special places and with corresponding space requirements. Another disadvantage is the use of material required to provide a space-forming structure for such a device. The possibility of operating such a device indoors in the home is severely restricted as a result. Furthermore, it is disadvantageous that use for other purposes is generally not possible.

The object of the invention is to provide a solution with which plants can be grown and raised under certain, controlled conditions in a simple manner, which also enables other types of use such as the Be provision of special storage conditions for plant products and which, in particular, indoors and with can be replaced in a small space.

confirmation copy The object is achieved by a device with the features listed in patent claim 1 and by an arrangement with the features listed in claim 8 . Preferred developments result from the respective dependent claims.

The phytoconditioning device according to the invention has a panel body, an LED light source, a fan and a power connection line. The phytoconditioning device is also referred to in the following for short as a panel.

The panel body has a flat basic shape and for this purpose a panel underside, a panel top side, a panel front side, a panel back side and two panel cheek sides.

In particular, the panel body is designed according to the invention for arrangement in a cabinet. This means that the panel body can be arranged in the same way as a shelf in a cupboard due to its flat design. In particular, a shelf in a cupboard can thus also be exchanged for the phytoconditioning device, for example. The panel body can be fastened in the cabinet in the same way as a shelf, but in any other suitable way, for example by means of slide-in rails, clamping devices or screw connections and other clamping, sliding, pull-out, screw, angle or drawer systems .

The LED light source is arranged in or on the panel body and has a light exit surface which is arranged on the underside of the panel.

The LED light source according to the invention preferably has an emission spectrum that is optimized for plant growth. The LED light source is particularly preferably also designed to emit further emission spectra. These other emission spectra are emission spectra that influence the metabolic processes of plant products, with the influence flow can be deceleration, acceleration or modification. Plant products are understood to mean, in particular, separated parts of plants such as fruits, fruits and vegetables. The plant products can be, for example, citrus fruits, berries, apples or cabbage and leafy vegetables. For example, the shelf life of citrus fruits can be increased through certain emission spectra by slowing down the metabolism. Conversely, the metabolism can be accelerated or modified by other emission spectra, so that post-ripening of products that were initially harvested immature can be induced. Furthermore, by modifying the metabolism, the formation of certain desired nutrients can be stimulated.

Furthermore, plant defense reactions can also be triggered by certain emission spectra in living plants, which lead to the formation of special secondary plant nutrients that are particularly valuable for human nutrition.

The functionality provided in this way advantageously includes post-ripening, delayed ripening and the formation of additional nutrients and vitamins in selected plant products such as tomatoes.

In particular, the possible flat and at the same time two-dimensional design of the LED light source is advantageous, as is its high energy efficiency and the associated low heat emission.

The fan is driven by an electric motor and is designed to provide an air flow between the underside of the panel and the top of the panel. Alternatively, the fan is designed to provide air circulation on the underside of the panel or on the top of the panel. In the first variant, air is sucked in on one side of the panel and discharged on the other side of the panel. In the second variant - the air circulation - additional air ducts are provided, which lead air duct openings in the side area. Depending on the running direction, the air is then sucked in by the fan and discharged through the air duct openings. give or vice versa. A characteristic of the second variant is that the air is sucked in and discharged on the same side of the panel, which can be either the underside of the panel or the top of the panel. There is therefore air recirculation on the respective side.

This air flow in the first variant or this air circulation in the second variant can be used, for example, to influence the humidity of the air surrounding the plant, referred to below as ambient air.

The fan is preferably arranged on the top side of the panel in such a way that air can be sucked in or let out even if, for example, a plant pot or other object is placed in the fan area. For this purpose, air ducts in the form of grooves or beads, which are open at the top and over longer areas, are preferably embedded in the upper side of the panel. It's also possible that the fan is slightly recessed and covered by a lattice structure.

The power connection line is arranged in the panel body and is designed to supply power to the LED light source and the fan.

The phytoconditioning device according to the invention has in particular the advantages described below.

The panel body forms a supporting structure which firstly allows the device according to the invention to be placed in a cabinet instead of a shelf without additional assembly requirements and secondly accommodates the units for controlling the environmental conditions. Advantageously, the support structure can also be designed in such a way that, thirdly, objects can be placed on it like on a standard shelf. The phytoconditioning device can thus advantageously use existing space structures. In particular, the phytoconditioning device can be used in a standard cupboard or kitchen cupboard.

The LED light source placed in the body of the panel is designed to provide the energy that the plant needs for photosynthesis and growth. For this purpose, the wavelength and intensity of the light is preferably matched to the plant species and can be regulated. The light emission from the panel is optimally aligned to its underside. The panel is preferably placed above the plants placed in a plant tray or flower pot, for example in a cupboard. In this way, the closed cupboard can be flooded with light that optimally hits the plant. Such a cabinet can advantageously also have glass doors, so that the user can create a visual reference to the plants and thus also have an advantageous decorative effect.

Particularly advantageously, the phytoconditioning device can also be used as intended for a special storage and treatment of plant parts such as fruit or vegetative plant parts, in particular edible fruit and vegetables. The particular advantage here is that the LED light source, possibly in conjunction with the fan, can create definable storage conditions that can influence the properties of such products in a targeted manner.

Furthermore, the fan is arranged in the panel body in such a way that it enables air to circulate in the closed cabinet. Air openings in the cupboard also enable a permanent exchange of air, which provides the plants with sufficient air. In order to supply the technical devices described, energy connection lines are laid in the panel body. These connect the electrical consumers with each other. A further connecting cable also leads out of the panel body and can preferably be connected to a standard socket of the house power network by means of a plug connector. The installation of the phytoconditioning device can be carried out by anyone, as no special knowledge is required due to the simple and closed structure.

The possible space-saving transport is also advantageous.

Another advantage is that it can be easily converted at any time. By replacing the phytoconditioning device with a shelf, a cupboard used for plants can be converted back to another normal use at any time.

In an advantageous development, the phytoconditioning device is characterized in that it has a control unit that is designed to control the operating states of the LED light source and the fan.

The control unit takes over the targeted control of the connected components. The fan and also the LED light source can be switched on and off in a targeted manner. The speed of the fan and thus the intensity of the air flow, but also the intensity and light color of the light source can be controlled using the control unit. For this purpose, the control unit preferably has an electronic circuit that is used for inputting, processing and outputting switching states. A microprocessor preferably serves as the heart of the control unit.

According to a further advantageous development, the phytoconditioning device is characterized in that it has a light color control module that is designed to control an emission spectrum of the LED light source. The controllability of the emission spectrum of the light source is essential for good plant growth. Different plant species require different intensities of different wavelengths. Sunlight offers a very wide spectrum of light colors. If the light supply is to be generated by an artificial light source, higher energy efficiency can be achieved by modifying the emission spectrum. In particular, in the case of LED light sources, the light can advantageously be generated by a plurality of different types of LEDs.

The targeted control of the LED light source for optimized plant cultivation is of great importance, both to achieve the best plant growth and to work energy-efficiently. This is particularly advantageous for use in a cupboard, since the heat generated here, which cannot always be dissipated well, is avoided.

In another advantageous development, the phytoconditioning device is characterized in that it has a sensor unit that is used to detect at least one environmental condition from the group:

- temperature

- Humidity

- Brightness is formed. It is also designed to provide the information about the environmental states obtained from this detection as environmental state data for the control unit so that it can be transmitted.

In order to be able to dynamically adapt the environmental conditions relevant to the plants, it is necessary to make the current status comprehensible. If data on temperature, humidity and brightness (photon flow and density) are available, the LED light source and the fan can be controlled according to an algorithm stored in the control unit. In this way, the environmental conditions for growing plants can be dynamically adjusted and optimized. Especially in an environment that is not ideal for plant cultivation, such as a kitchen cupboard, the conditions can be affected by an electronic niche control can be adapted to the needs of the corresponding plant.

According to a further advantageous development, the phytoconditioning device is characterized in that it has a control panel that is designed to input switching commands.

This enables the user to adapt the device to the local conditions and the type of plant currently being cultivated and preferably to influence the control algorithm. In addition to switches for input, a signaling unit in the form of luminous elements or a display is preferably also attached to the control panel, which informs the user about the different operating states of the device or about environmental states. In this way, the operating status and any errors that may have occurred can be recognized by the user, and a response can then be made. The control panel is preferably arranged on the front side of the panel. This allows operation in the installed state after opening the cabinet door.

In another advantageous development, the phytoconditioning device is characterized in that the control unit has a wireless data interface and is designed for data transmission connection with a mobile terminal device.

The connection can be set up locally, for example via Bluetooth, or internet-based, for example via WLAN. Through the connection to a mobile end device, the interaction of the user with the device and the utilization and analysis of the recorded information is much easier and more comprehensive than operation on a control panel. The long-term recording of the data during plant cultivation also enables an analysis and adjustment of future processes. In addition, with an optional connection to the Internet, a large information storage device can be accessed can be accessed to find a solution in the event of problems or optimization of the process. Furthermore, this makes it possible to recognize switching states and errors and to carry out an operation without opening the cabinet, since opening the cabinet would have a direct effect on the environmental conditions. This significantly expands the range of functions of the device. Permanent technical updating is also advantageously made possible by installing new device software on the controller of the device. In this way, the range of functions can be improved during the product life cycle.

According to a next advantageous development, the phytoconditioning device is characterized in that the panel body has a shaped section—preferably several shaped sections—for receiving shelf supports. An existing shelf of a kitchen cupboard can be removed and the device can be used instead. It is placed on the existing shelf supports. Installation is possible with just a few simple steps, which can be easily carried out by a user without manual skills. The phytoconditioning device is fixed securely by means of the mold sections.

According to a further aspect of the invention, the object is achieved by a phytoconditioning arrangement.

The phytoconditioning arrangement is characterized in that it has at least two phytoconditioning devices. The at least two phytoconditioning devices are designed according to one of the preceding claims.

In the phytoconditioning arrangement according to the invention, the panels are preferably arranged one above the other and spaced apart in such a way that a plant can be placed in the space formed in this way on the respective lower phytoconditioning device directly or optionally via a support and supplied with LED light from the respective upper phytoconditioning device . It several panels can be inserted in a cabinet and the available space can be optimally used.

Depending on the space available, a large number of panels can be arranged. The capacity for growing plants can be increased as desired within the framework given by the space available.

In an advantageous development, the phytoconditioning arrangement is characterized in that the phytoconditioning devices have a data connection with one another, which is designed for data exchange between the control units.

Several panels installed in a cabinet can thus be operated in a coordinated manner. In this way, the individual panels do not interfere with each other or have a negative impact on the environmental conditions. In particular, for example, the operating status of a fan of the panel on which the plant is standing can interact with the LED light source of the panel arranged above it in optimizing the environmental conditions for the plant in question.

The joint coordination also minimizes the operating and support effort by the user. It can preferably be sufficient to make the optimal settings on just one panel and the other panels follow the selected specifications. The data connection is preferably designed as a standardized bus system. In this way, the number of coupled devices can essentially be increased at will. An integration of other systems or in other systems is possible.

The invention is an exemplary embodiment based on 1 shown as a schematic oblique representation of the phytoconditioning device,

2 as a schematic oblique representation of the phytoconditioning arrangement, explained in more detail.

In this case, the same reference symbols in the various figures refer to the same features or components in each case. The reference symbols are also used in the description if they are not shown in the relevant figure.

FIG. 1 shows an exemplary embodiment in a schematic oblique representation of the phytoconditioning device viewed obliquely from below.

This shows the panel body 1 which, as the base body, accommodates all the elements of the device. This includes the LED light source 3, which is attached to the panel underside 1.2. In between is located in the middle of the panel body 1 of the fan 4. The air ducts run between the top of the panel 1.1 and the bottom of the panel 1.2. The fan 4 is used to generate an air flow. The control panel 6 is located on the front side of the panel 1.3. This is used for interaction with the user. To accommodate the phytoconditioning device in a cupboard, shaped sections 7 are attached to the panel body 1, specifically to the underside of the panel body 1.2, into which the shelf supports of a cupboard can engage.

FIG. 2 shows an exemplary embodiment of the phytoconditioning arrangement in a schematic oblique representation.

In the exemplary embodiment, this consists of two phytoconditioning devices 8.1, 8.2, arranged in a cabinet 2. The phytoconditioning devices 8.1, 8.2 each replace a cabinet floor and are fitted on fittings in the Added cabinet, which engage in the mold sections 7 on the panel underside of the panel body 1 1.2. By means of the LED light source 3 and fan 4 of the phytoconditioning devices 8.1, 8.2, a climate is generated in the cabinet that promotes plant rearing. The user can use the control panel 6 to make various settings that specify the general conditions for climate control.

Since several phytoconditioning devices 8.1, 8.2 are used, their operating states are coordinated with one another. For this purpose, there is a connection to one another via an energy supply line 5, which also provides a data connection between the two devices. In an alternative embodiment, the data connection takes place separately from the power supply line 5, the data connection being provided wirelessly via radio in this embodiment.

Reference signs used

1 panel body

1.1 Panel top

1.2 Panel underside

1.3 Panel face

2 closet

3 LED light source

4 fans

5 power connection line

6 control panel

7 mold section

8.1 Phytoconditioning device

8.2 additional phytoconditioning device

Claims

patent claims

1. Phytoconditioning device (8), comprising a panel body (1), an LED light source (3), a fan (4) and an energy connection line (5), wherein the panel body (1) has a panel top side (1.1), a panel bottom side (1.2 ), a panel front side (1.3), a panel rear side and two panel cheek sides and is designed in a flat basic shape and for arrangement in a cabinet (2), the LED light source (3) in or on the panel body (1) and a light exit surface the LED light source is arranged on the underside of the panel (1.2), the fan (4) being driven by an electric motor and designed to provide an air flow between the underside of the panel (1.2) and the top of the panel (1.1), or air circulation on the underside of the panel (1.2) or provided on the panel top (1.1) and wherein the power connection line (5) is arranged in the panel body (1) and is designed to supply power to the LED light source (3) and the fan (4). t.

2. Phytoconditioning device (8) according to claim 1, characterized in that it has a control unit which is designed to control operating states of the LED light source (3) and the fan (4).

3. Phytoconditioning device (8) according to claim 1 and 2, characterized in that it has a light color control module which is designed to control an emission spectrum of the LED light source (3).

4. Phytoconditioning device (8) according to one of the preceding claims, characterized in that it has a sensor unit which is designed to detect at least one environmental condition from the group:

- temperature

- Humidity

- Brightness and that this is designed to provide ambient state data for the control unit that can be transmitted as the detection.

5. Phytoconditioning device (8) according to any one of the preceding claims, characterized in that it has a control panel (6) which is designed for the input of switching commands.

6. Phytoconditioning device (8) according to one of the preceding claims, characterized in that the control unit has a wireless data interface and is designed for data transmission connection with a mobile terminal device.

7. phytoconditioning device (8) according to any one of the preceding claims, characterized in that the panel body (1) has a shaped section (7) for receiving shelf supports.

8. Phytoconditioning arrangement, characterized in that it has at least two phytoconditioning devices (8) according to one of the preceding claims.

9. Phytoconditioning arrangement according to claim 8, characterized in that the phytoconditioning devices (8) have a data connection with one another, which is designed for data exchange between the control units.

ALSO TWO PAGES OF DRAWINGS