DE102020007129A1 - Interchangeable insert for a seed pot of a hydroponic system and hydroponic system in question - Google Patents

Abstract

The invention relates to an exchangeable insert for a seed pot of a hydroponic system, with a closable cover for receiving plant seeds, the cover being made of an at least partially permeable material which is designed to allow plants to grow through the cover that the insert has a fluid conductor which is adapted to supply the plant seeds in the casing with fluid, the fluid conductor having or being formed from a glass fiber cord. The invention also relates to a hydroponic system.

Description

The invention relates to an exchangeable insert for a seed pot of a hydroponic system, with a closable cover for receiving plant seeds, the cover being made of an at least partially permeable material which is designed to enable plant growth through the cover. The invention also relates to a hydroponic system.

Hydroponic systems are well known in the art. They are based on the basic principle that the plants grown with such a system do not primarily take root in the ground, but rather in containers filled with water. In addition to industrial applications, hydroponic systems are increasingly being used by end users. Such a system is, for example, from U.S. 2005/0274073 A1 known. Here exchange containers are provided, which are used in the hydroponic system in question. The exchange containers contain the plant seeds and are exchanged after the plants have finished flowering.

The disadvantage of such container solutions known from the prior art is that the water supply to the containers in question usually has to be provided using additional pumps and the containers together with the housing, which is often made of plastic or the like, have to be disposed of after use, resulting in a significant amount of waste is produced and the containers take up a comparatively large volume overall. In addition, casings filled with plant seeds are known from the prior art, which allow plants to grow through the casings in question. The disadvantage of such cases, however, is that they are not set up for use with hydroponic systems for the end user, they generate largely undirected plant growth and the supply of the relevant cases with fluid is complex.

Against this background, the invention was based on the object of specifying an insert for a seed pot of a hydroponic system that overcomes the disadvantages found in the prior art as far as possible. In particular, an insert for a seed pot was to be specified which is compatible with hydroponic systems for the end user and ensures an efficient fluid supply to the plant seeds.

According to the invention, the object is achieved with an exchangeable insert of the type mentioned at the outset in that the insert has a fluid conductor which is designed to supply the plant seeds in the casing with fluid, the fluid conductor having or being formed from a glass fiber cord (claim 1 ).

The invention makes use of the knowledge that the fluid guide having or formed from a glass fiber cord enables a reliable supply of fluid to the plant seeds by connecting the fluid guide to a fluid source, with the glass fiber advantageously enabling a well-dosed amount of fluid without the use of additional pumps to supply the plant seeds and thus ensure optimized plant growth. Such an exchangeable insert is also easy for the end user to handle and has only a small volume. Compared to systems known from the prior art, in which an entire container containing plant seeds and other raw materials has to be exchanged, replacing the insert is ecologically advantageous and enables the inserts to be transported in a smaller volume compared to those from the prior art known solutions.

According to a second aspect of the invention or according to an advantageous development of the invention according to the first aspect, it is proposed according to the invention that the casing has plant fibers or is formed from them, the plant fibers in particular having at least one of the following: cotton, cellulose, pulp, paper, Banana fiber, hemp fiber, abacá. According to the second aspect of the invention or according to the advantageous development of the invention according to the first aspect, a particularly durable design of the casing is provided. The plant fibers are not only a natural raw material for the production of the casing, but a casing designed in this way is also ecologically recyclable. In comparison to pots known from the prior art, mostly made of plastic, the second aspect of the invention makes it possible to provide replaceable inserts that are particularly environmentally friendly.

The invention is further developed in that the cover has an opening with a closure which is designed to completely or at least partially close the cover, the closure being in particular designed as a cord closure. Such a closure makes it possible to fill the casing in a simple manner and to securely close it.

According to a preferred embodiment, at least one of the following is present in the shell taken: plant seeds, substrate, especially an organic substrate with organic additives. In other words, in addition to the plant seeds required for plant growth, the shell can contain other ingredients, in particular a substrate. It is envisaged that the composition of plant seeds and substrate is tailored to the respective plant type. For example, for a particular type of plant it may be sufficient to place only plant seeds in the envelope. For another type of plant, a combination of plant seeds and substrates and, for example, other growth-promoting ingredients can also be advantageous.

Furthermore, the fluid conductor is preferably guided through the closure into the shell or is arranged on the outside in contact with the shell. In this way, the closure, in particular the cord closure, can provide an easily detachable and lockable access option for the fluid conductor into the sleeve. The routing of the fluid conductor lying on the outside of the shell has proven to be a further advantageous possibility for reliably supplying the inside of the shell with fluid.

According to a further preferred embodiment, the glass fiber cord has a length of 160 mm to 240 mm, in particular 190 mm to 210 mm. The length in question or the length range in question has proven to be particularly advantageous, on the one hand providing sufficient flexibility with regard to the arrangement of the insert relative to a fluid source, while on the other hand the length range in question ensures that the inside of the casing is reliably supplied with the desired fluid volume flow becomes.

The invention is further developed in that the glass fiber cord has a diameter of 3 mm to 8 mm, in particular 5 mm to 6 mm. The diameter range in question has proven to be particularly suitable for providing the insert with the desired and well-dosed amount of fluid.

The invention has been described above with reference to a replaceable liner for a seed pot of a hydroponic system. In a further aspect, the invention relates to a hydroponic system for growing plants, in particular for growing plants indoors, with a fluid tank, a seed pot receptacle for receiving at least one seed pot and at least one seed pot.

The invention solves the problem described at the outset in relation to the hydroponic system, in which the seed pot is set up to accommodate at least one insert according to one of the above exemplary embodiments. The seed pot itself is preferably detachably arranged in the seed pot receptacle. It is advantageously ensured according to the invention that the seed pot itself can be used for a large number of plant-rearing processes and only the insert needs to be exchanged, for example after a plant has finished blooming. In this way, the amount of waste generated during the operation of the system is reduced.

The invention is further developed in that the seed pot has a housing with an upper side, an underside opposite the upper side, and a wall arranged between the upper side and the lower side, the housing being at least partially open on the upper side and having an inner chamber for receiving the interchangeable insert forms. Such a housing not only forms a receptacle for the exchangeable insert, but also defines a preferred growth direction of the plants forming from the insert through the housing opening on the top. The housing can also be used for a variety of growth processes.

According to a preferred embodiment, the housing has at least one separating element on the inside, which divides the inner chamber into at least two inner chambers. This makes it possible to use different sized inserts with a single seed pot. If, for example, a comparatively larger insert is used, the separating element is not inserted. However, if smaller inserts are to be used in comparison, the seed pot can be divided into two inner chambers and then two different inserts can be used in one seed pot. In this way, the seed pot can be adapted to different purposes in a modular and cost-effective manner.

The separating element is preferably arranged on the housing in a fixed or detachable manner. In addition to the detachable arrangement of the separating element just described, an alternative embodiment provides for the separating element to be arranged in a fixed manner in the housing.

The invention is further developed in that at least one, preferably each of the chambers has a housing opening for the passage of the fluid conductor. In the event that no separating element is inserted into the housing and, in other words, the housing forms a single inner chamber, any of the housing openings can be used to lead the fluid conductor through in the direction of the fluid tank.

According to a preferred embodiment, the at least one opening is arranged in the housing wall at a distance from the underside of the housing. This arrangement makes use of the finding that by spacing the opening from the underside of the housing, the housing as a whole can be at least partially arranged in the fluid tank without fluid flowing through the opening into the seed pot and flooding the seed pot. In this way, the overall vertical extent of the hydroponic system can be reduced, making the system more compact overall.

Preferably, the opening is spaced from the underside of the housing by 45 mm to 75 mm, in particular 55 mm to 65 mm. This area has proven to be particularly preferable in order to ensure that the fluid conductor can be carried out easily and to ensure a secure connection of the fluid conductor to the fluid tank, while at the same time allowing the seed pot to be arranged at least partially in the tank area.

The top and bottom of the housing preferably have a substantially rectangular basic shape. The housing preferably tapers from the top to the bottom. According to a preferred embodiment, the housing has at least one, preferably two, indentations in the area of the wall. Each of the indentations preferably has the opening at an upper side of the indentation. The opening preferably has a diameter of 5 mm to 10 mm. The wall is preferably arranged continuously between the bottom and the top.

The invention is further developed in that the hydroponic system has a lighting unit, the lighting unit having at least one light source, in particular an LED light source, and a reflector. In this way, the hydroponic system becomes independent of external light sources and can be used indoors.

According to a preferred development, the fluid tank has a filling level sensor which is set up to sense a filling level of the fluid tank. In this way, it is possible to inform the user in good time that the fluid tank is too low.

According to a preferred development, the hydroponic system has a control unit which is connected to the lighting unit and/or the level sensor in a signal-conducting manner, and a data transmission interface which is connected to the control unit in a data-conducting manner and is set up to communicate wirelessly with a data network and/or a mobile terminal device . In this way, remote control of the system, in particular the lighting unit, is possible and, in addition, remote access to a fill level measurement value of the fluid tank generated by the fill level sensor. Using a mobile terminal device, for example a mobile phone or a tablet, the user can thus influence the control, in particular the lighting control, of the hydroponic system and the user is also able to remotely monitor the filling level of the fluid tank.

According to a preferred embodiment, the data transmission interface is set up to communicate with the data network and/or the mobile terminal device using at least one of the following data transmission standards: Bluetooth, Bluetooth Low Energy, Near Field Communication, W-LAN, ZigBee, EnOcean, Z-Wave, Proprietary protocol in the 868 MHz band (ISM band), JTAG debugging interface.

Furthermore, the seed pot preferably has at least one replaceable insert according to one of the above exemplary embodiments.

In a further aspect, the invention relates to a seed pot for a hydroponic system for receiving an exchangeable insert, in particular an exchangeable insert according to one of the above exemplary embodiments.

The invention solves the problem described at the outset in relation to the seed pot, in that the seed pot has a housing with an upper side, an underside opposite the upper side, and a wall arranged between the upper side and the lower side, the upper side and the lower side having a substantially rectangular Have a basic shape, and wherein the housing tapers from the top to the bottom, the housing being at least partially open at the top and forming an inner chamber for receiving the replaceable insert, the chamber having a housing opening for the passage of the fluid conductor, wherein the opening is arranged in the housing wall at a distance from the underside of the housing, and at least one separating element which divides the inner chamber into at least two inner chambers is arranged on the inside of the housing.

The seed pot enjoys the same advantages and preferred embodiments as the hydroponic system of the present invention and vice versa. In this regard, the above Aus referenced and their content included here.

Further features and advantages of the invention result from the appended claims and the following description, in which exemplary embodiments are explained in detail with the aid of schematic drawings.

• 1 ein erfindungsgemäßes Hydroponiksystem in einer perspektivischen Darstellung;
• 2 einzelne Baugruppen des erfindungsgemäßen Hydroponiksystems gemäß 1 in einer perspektivischen Darstellung;
• 3, 4 ein erfindungsgemäßen Saattopf in perspektivischen Darstellungen;
• 5 ein Trennelement für ein erfindungsgemäßen Saattopf in einer Seitenansicht;
• 6 den erfindungsgemäßen Saattopf gemäß den 3 und 4 mit eingesetzten Trennelement in einer Draufsicht;
• 7, 8 ein erfindungsgemäßer Einsatz für einen Saattopf in schematischen Seitenansichten.

Show in detail:

• 1 a hydroponic system according to the invention in a perspective view;
• 2 individual components of the hydroponic system according to the invention 1 in a perspective view;
• 3 , 4 a seed pot according to the invention in perspective views;
• 5 a separating element for a seed pot according to the invention in a side view;
• 6 the seed pot according to the invention 3 and 4 with inserted separating element in a plan view;
• 7 , 8th an inventive insert for a seed pot in schematic side views.

1 shows a hydroponic system 2 for growing plants. The hydroponic system 2 is designed in particular to be used for cultivating plants indoors. The hydroponic system 2 has a fluid tank 4 and a base plate 5 arranged on top of the fluid tank 4 . A total of six seed pot receptacles 6 are formed in the base plate 5 . The seed pot receptacles 6 have essentially rectangular recesses. A seed pot 8 is arranged in each of the seed pot receptacles 6 . The seed pot 8 is designed to have at least one replaceable insert 54 (not shown here, cf. 7 and 8th ) record. A roof assembly 10 is connected to the fluid tank 4 or the base plate 5 via a frame 12 .

The roof assembly 10 has a lighting unit 14 . The lighting unit 14 has an LED light source 16 and a reflector 18 . A filling level sensor 20 is arranged in the area of the fluid tank 4 . The fill level sensor 20 is set up to sense the fill level of the fluid tank 4 . The level sensor 20 is in 1 shown schematically. The hydroponic system 2 also has a control unit 22 . The control unit 22 is connected to the lighting unit 14 and the filling level sensor 20 in a signal-conducting manner. A data transmission interface 24 is in turn connected to the control unit 22 in a data-conducting manner. The data transmission interface 24 is set up to communicate wirelessly with a data network 26 and a mobile terminal device 28 .

2 shows selected assemblies of the hydroponic system 2 in an exploded view. Accordingly, the base plate 5 has a lower guide area which corresponds to an opening of the fluid tank 4 on the upper side. The base plate 5 also has depressions 9 which make it easier to remove the seed pots 8 from the base plate 5 . The seed pots 8 have an upper, protruding edge 33 (cf. 3 ) that rests on the base plate 5. In this way, the seed pot 8 remains easily removable.

3 shows a seed pot 8 . The seed pot 8 has a housing 30 . The housing 30 has a top 32 . The top 32 has the peripheral projecting edge 33 . The housing 30 also has an underside 34 opposite the top 32 . The top 32 and the bottom 34 each have a substantially rectangular cross-section. A wall 36 is arranged between the upper side 32 and the lower side 34 . The wall 36 is circumferential and connects the bottom 34 to the top 32 in a fluid-tight manner. The housing 30 is designed to be open at the top 32 . The housing 30 defines an interior chamber 38 for receiving one or more inserts 54 . The housing 30 tapers from the upper side 32 towards the lower side 34. The housing 30 has an indentation 44 in each case in the region of side surfaces 39 of the wall 36. The indentation 44 is directed toward an interior of the housing 30 . The indentation 44 runs only in sections over the entire height of the housing 30. The indentation has an upper side 46 in which a housing opening 40 is made (cf. 4 ). The housing opening 40 is spaced from the bottom 34 of the housing 30 by a distance 42 .

As with reference to the in 4 As can be seen in the top view shown, the seed pot 8 also has receptacles 48 for a separating element 49 . With the help of the separating element 49, the inner chamber 38 can be divided into two partial chambers 50, 52 (cf. 6 ) are subdivided. The seed pot 8 has two housing openings 40 . The housing openings 40 are arranged on the respective upper sides 46 of the indentations 44 .

5 shows the separating element 49. The separating element 49 tapers starting from an upper side 51 in the direction of a lower side 53 corresponding to the tapering configuration of the housing 30. The separating element 49 has on its upper side 51 a projection 55 which corresponds to the corresponding upper-side receptacle for the separating element 48 in the housing 30 of the seed pot 8 .

As 6 can be removed, the separating element 49 divides the housing 30 into a first sub-chamber 50 and a second sub-chamber 52. Each of the sub-chambers 50, 52 has a corresponding housing opening 40, from which a fluid conductor 58 (cf. 7 and 8th ) of the insert 54 can be guided into the fluid tank 4.

7 shows an exchangeable insert 54 for use in the seed pot 8. The insert 54 has a closable cover 56 for receiving plant seeds 62 (cf. 8th ) on. The shell 56 is formed from an at least partially permeable material configured to allow plant growth through the shell 56 . The shell 56 has a rectangular basic shape. The insert 54 also has a fluid conductor 58 . The fluid conductor 58 is set up to supply an envelope interior 60 with fluid. The fluid conductor 58 is designed as a glass fiber cord 64 . The shell 56 has an opening 66 with a closure 68 . The closure 68 is designed to completely or at least partially close the sleeve 56 . The closure 68 is designed in particular as a cord closure 70 . In the in the 7 shown embodiment, the glass fiber cord 64 is guided through the shell opening 66 into the shell interior 60.

In the in the 8th shown embodiment, the fluid conductor 58 runs along an outer side of the casing 61. 8th it can also be seen that plant seeds 62 and substrate 72 are accommodated in the cover 56 . The fluid conductor 58, designed as a glass fiber cord 64, has a length of 74 and a diameter of 56.

Reference List

2

hydroponic system

4

fluid tank

5

base plate

6

seed pot pickup

8th

seed pot

9

trough

10

roof assembly

12

frame

14

lighting unit

16

LED bulbs

18

reflector

20

level sensor

22

control unit

24

data transmission interface

26

data network

28

mobile device

30

Housing

32

top

33

protruding edge

34

bottom

36

wall

38

inner chamber

39

side faces

40

case opening

42

spacing

44

indentation

46

top of the indentation

48

Holder for separating element

49

separator

50

First sub-chamber

51

Top divider

52

Second sub-chamber

53

Underside divider

54

mission

55

head Start

56

Covering

58

fluid conductor

60

case interior

61

case exterior

62

plant seeds

64

fiberglass cord

66

shell opening

68

closure

70

cord closure

72

substrate

74

Fiberglass cord length

76

Diameter of fiberglass cord

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• US 2005/0274073 A1 [0002]

Claims (20)

Replaceable insert for a seed pot of a hydroponic system, with a closable cover for receiving plant seeds, the cover being made of an at least partially permeable material which is designed to allow plant growth through the cover, characterized in that the insert has a Fluid conductor which is adapted to supply the plant seeds in the casing with fluid, the fluid conductor having or being formed from a glass fiber cord. The use according to the generic term of claim 1 or after claim 1 , characterized in that the casing has plant fibers or is formed therefrom, the plant fibers in particular having at least one of the following: - cotton, - cellulose, - cellulose, - paper, - banana fibers, - hemp fibers, - abaca. The use after claim 1 or 2 , characterized in that the cover has an opening with a closure which is designed to completely or at least partially close the cover, the closure being in particular designed as a cord closure. The insert according to one of the preceding claims, characterized in that at least one of the following is accommodated in the casing: - plant seeds, - substrate, in particular an organic substrate with organic additives. The use after claim 3 or 4 , characterized in that the fluid conductor is guided through the closure into the shell or is arranged outside adjacent to the shell. The insert according to one of the preceding claims, characterized in that the glass fiber cord has a length of 160 mm to 240 mm, in particular 190 mm to 210 mm. The insert according to one of the preceding claims, characterized in that the glass fiber cord has a diameter of 3 mm to 8 mm, in particular 5 mm to 6 mm. A hydroponic system for cultivating plants, in particular for cultivating plants indoors, with a fluid tank, a seed pot receptacle for receiving at least one seed pot, and at least one seed pot, characterized in that the seed pot is designed to have at least one replaceable insert according to one of the above take up claims. The hydroponic system after claim 8 , characterized in that the seed pot has a housing with a top, a bottom opposite the top, and a wall arranged between the top and the bottom, the housing being at least partially open at the top and an inner chamber for receiving the replaceable insert trains. The hydroponic system after claim 9 , characterized in that at least one separating element is arranged on the inside of the housing, which divides the inner chamber into at least two inner chambers. The hydroponic system after claim 10 , characterized in that the separating element is fixedly or detachably arranged on the housing. The hydroponic system according to one of the claims 9 until 11 , characterized in that at least one, preferably each of the chambers, has a housing opening for the passage of the fluid conductor. The hydroponic system after claim 12 , characterized in that the at least one opening is arranged at a distance from the underside of the housing in the housing wall. The hydroponic system after Claim 13 , characterized in that the opening is spaced from the underside of the housing 45 mm - 75 mm, in particular 55 mm to 65 mm. The hydroponic system according to one of the Claims 8 until 14 , characterized by a lighting unit, wherein the lighting unit has at least one light source, in particular an LED light source, and a reflector. The hydroponic system according to one of the Claims 8 until 15 , characterized in that the fluid tank has a level sensor which is adapted to sense a level of the fluid tank. The hydroponic system according to one of the Claims 15 or 16 , marked by a control unit which is connected to the lighting unit and/or the filling level sensor in a signal-conducting manner, and a data transmission interface which is connected to the control unit in a data-conducting manner and is set up to communicate wirelessly with a data network and/or a mobile terminal device. The hydroponic system after Claim 17 , characterized in that the data transmission interface is set up to communicate with the data network and/or the mobile terminal device by means of at least one of the following data transmission standards: - Bluetooth, - Bluetooth Low Energy, - Near Field Communication, - W-LAN, - ZigBee, - EnOcean, - Z-Wave, - Proprietary protocol in the 868 MHz band (ISM band), - JTAG debugging interface. The hydroponic system according to one of the Claims 8 until 18 , characterized in that the seed pot has at least one interchangeable insert according to one of Claims 1 - 7 having. A seed pot for a hydroponic system for receiving a replaceable liner, particularly a replaceable liner according to any one of Claims 1 - 7 , characterized in that the seed pot has a housing with an upper side, an underside opposite the upper side, and a wall arranged between the upper side and the lower side, the upper side and the lower side having a substantially rectangular basic shape, and the housing of tapering from the top to the bottom, the housing being at least partially open at the top and forming an inner chamber for receiving the replaceable insert, the chamber having a housing opening for the passage of the fluid conductor, the opening being at a distance from the bottom of the housing in the housing wall is arranged, and wherein at least one separating element is arranged on the inside of the housing, which divides the inner chamber into at least two inner chambers.

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