WO2021228934A1 - Modular breeding system for insects - Google Patents

Abstract

There is provided a modular breeding system (1) for insects comprising at least one breeding box (2) for accommodation and breeding of insects and comprising at least one technical box (3) for supply of conditioned air to the breeding box (2), which modular breeding system (1) is of simple and cost-effective construction and which modular breeding system (1) can be adapted to different production quantities of insects as simply and flexibly as possible. The modular breeding system (1) is distinguished by the fact that the technical box (3) has provided thereon an outlet opening (5) for the conditioned air, that the breeding box (2) has provided thereon a supply air channel (6) which connects a bottom side of the breeding box (2) to an opposite top side of the breeding box (2), wherein the supply air channel (6) has a first open supply air channel end (6a) on the bottom side and has an opposite second open supply air channel end (6b) on the top side, that the supply air channel (6) between the supply air channel ends (6a, 6b) has provided thereon a supply air opening (7) which connects the supply air channel (6) to an internal space of the breeding box (2), and that the breeding box (2) is arrangeable on the technical box (3) in a stackable manner such that the outlet opening (5) of the technical box (3) is connected to the first supply air channel end (6a) of the supply air channel (6) of the breeding box (2), with the result that the conditioned air is suppliable to the internal space of the breeding box (2) from the technical box (3) via the supply air channel (6) and the supply air opening (7).

Description

Modular breeding system for insects

The invention relates to a modular breeding system for insects with a breeding box for receiving and breeding insects and with a technology box for supplying the breeding box with conditioned air. The invention also relates to a use of the breeding system for breeding insects.

In industrial insect breeding, insect larvae usually mature in boxes over a period of several days to several weeks. On an economically sensible scale, a farm comprises a large number of such boxes. These boxes can be stacked on pallets, individually stacked or individually stored on shelves. In order to achieve a better use of space, the used pallets with the stacked boxes can also be stored in high-bay warehouses or arranged in a very close arrangement on one level. By using boxes, widespread machines can be used to manipulate boxes and pallets. The boxes used have openings on one or more sides to ensure adequate exchange with the ambient air. The ambient air can be conditioned accordingly by a technical device, such as heating or cooling or humidifying or dehumidifying.

Through the exchange, thermal energy and moisture are supplied and removed from the boxes in order to achieve the desired climatic conditions for optimal larvae growth. These conditions can be, for example, 27 ° C and 60% relative humidity. In order to support this exchange, air movement in the storage room is often forced through technical devices such as fans, or parts of the boxes can be made of an air-permeable or perforated material so that air can circulate within boxes stacked on top of one another.

In insect breeding at home, in addition to the open boxes described for insect breeding, closed boxes are also used. These boxes can also be placed in a specially made shelving system and have additional devices that are provided, for example, for laying eggs or for separating the various life stages of the insects. These closed boxes can have individual or central ventilation and heating in order to achieve the desired climatic conditions within the boxes.

From experience in breeding on a small scale, the optimal conditions for the rapid growth of the larvae are known. So on the one hand the environmental conditions and the ventilation can be adapted to the respective condition of the larvae (e.g. age) and, on the other hand, the humidity can be regulated. With these measures, a significant increase in the fattening yield can be achieved. In the implementation on a large scale, for example using a high-bay warehouse, there are a number of problems here. One problem is to provide the larvae with sufficient water in an inexpensive manner without causing mold to grow. One way of irrigating the larvae is to take the pallets out of the warehouse several times a day and water them at a central point. However, the handling of pallets required for this is technically difficult to implement or economically sensible only with a fully automated pallet warehouse. Which means considerable investment costs. Another option is stationary, decentralized irrigation using piping in the high rack. This is also very costly and technically difficult to implement due to the changing positions of the pallets.

At present, therefore, irrigation is largely avoided in industrial breeding or attempts are made to cover the water requirement by increasing the air humidity or adding fresh vegetables. However, this is only insufficiently possible due to the risk of mold formation. In small farms, irrigation is also carried out manually, which, however, is associated with increased personnel costs and cannot be implemented within a high-bay warehouse. Another problem is to ensure the air conditioning of the high-bay warehouse, which represents a significant expense in terms of investment volume and ongoing operating costs. This also restricts the selection and minimum size of the location, as smaller systems are often uneconomical. In addition, the climatic conditions and ventilation should be adapted to the age of the larvae. One possibility is to subdivide the camp into different, smaller climatic zones so that there is one climatic zone for each age group. However, this is associated with significant additional costs. Another option is to fill the entire warehouse with just one age group. However, this results in a very inefficient utilization of the production facility. Another problem is determining the condition of the larvae and the breeding environment remotely without direct interaction. Only then is real automation of the rearing possible, as the naturally existing variation can be compensated for, e.g. determining the right time for refeeding or harvesting.

Known systems are disclosed in US 2020/0205369 A1, US 2018/0077912 A1, DE 202018 107092 U1, EP 3032 944 B1, EP 0676918 B1, EP 2 820948 A1, US 2013/0319334 A1 or CN 106386700 A, for example. It is therefore the object of the present invention to provide a breeding system for insects that is simple and inexpensive to set up and that can be adapted as simply and flexibly as possible to different production quantities of insects.

According to the invention, the object is achieved in that an outlet opening for the conditioned air is provided on the technology box, that an air inlet duct is provided on the cultivation box, which connects an underside of the cultivation box with an opposite upper side of the cultivation box, the inlet air duct being a first on the underside has an open inlet duct end and on the upper side has an opposite, second open inlet duct end, that an inlet air opening is provided on the inlet air duct between the inlet air duct ends, which connects the inlet air duct with an interior of the grow box, and that the grow box can be stacked on the technology box in such a way that the outlet opening of the technology box is connected to the first end of the supply air duct of the supply air duct of the cultivation box, so that the conditioned air from the technology box can be supplied to the interior of the cultivation box via the supply air duct and the supply air opening. This creates a simply structured system that can be flexibly expanded so that it can be adapted to different production quantities. As a result of the essentially closed breeding system, desired environmental conditions can be set in the breeding box, which enable the insects to grow better. As a result, it is no longer necessary, as was previously the case in the prior art, that the entire environment, such as an entire production hall, has to be conditioned to specific environmental conditions and different environmental conditions can advantageously also be generated in different cultivation boxes or groups of cultivation boxes. The addition of moisture in industrial insect breeding by means of high-bay warehouses can thus be achieved without significant pallet turnover, personnel expenses or complex piping, as well as without the addition of fresh vegetables. The targeted introduction of moisture also prevents the formation of mold. A self-contained system is provided, which can be individually air-conditioned and is isolated from the environment. As a result, the demands on the insulation of the high-bay warehouse can be reduced or a reduction in energy consumption can be achieved. Thanks to the modular structure of the breeding system, a large number of locations that are unsuitable for conventional methods can be developed.

An exhaust air duct is preferably provided on the cultivation box, which connects an underside of the cultivation box with an opposite top side of the cultivation box, the exhaust air duct having a first open exhaust air duct end on the underside of the cultivation box and an opposite, second open exhaust air duct end on the upper side of the cultivation box, with the Exhaust duct between the exhaust duct ends an exhaust duct opening is provided which connects the exhaust duct with the interior of the breeding box, so that Used exhaust air can be discharged from the interior of the cultivation box via the exhaust air duct opening and the exhaust air duct from the cultivation box, the exhaust air duct preferably being arranged on a side of the cultivation box opposite the supply air duct. As a result, a common discharge from several cultivation boxes can also be made possible for the exhaust air, similarly to the supply air. If necessary, a central discharge can also take place via the technology box.

It is advantageous if the supply air duct is structurally integrated into the grow box or is arranged in the form of an external duct on an outside of the grow box and / or if the exhaust air duct is structurally integrated into the grow box or in the form of an external duct on an outside of the grow box is. It is particularly advantageous if the structurally integrated supply air duct and / or exhaust air duct are formed by a multi-walled side wall of the cultivation box. A simple and robust modular system can be created through the integrated channels and, similar to cooling channels, heat can also be exchanged via heat conduction through the integrated side wall. External channels have the advantage that existing grow boxes can easily be retrofitted.

Optionally, a deflection device or a damper for generating a pressure gradient can be provided in the supply air duct and / or in the exhaust air duct, the deflection device preferably being formed by an at least three-walled side wall of the cultivation box. As a result, the same pressure conditions as possible can be created in the grow boxes.

In the cultivation system, a closure element is preferably also provided, which can be arranged on the top of the cultivation box in order to close the cultivation box and / or the second inlet air duct end of the inlet air duct and / or the second outlet air duct end of the exhaust air duct. As an alternative or in addition, the supply air duct and / or the exhaust air duct can also be designed to be self-closing in order to close the second supply air duct end of the supply air duct and / or the second exhaust air duct end of the exhaust air duct. This means that cultivation boxes that are open at the top can be used, with the upper box closing the lower box. The top box and at least the inlet duct end can be closed in a simple manner by the closing element.

At least one, preferably self-closing, connection port for connecting an external conditioning system or for connecting a further technology box is advantageously provided on the technology box, with at least two connection ports preferably being provided on opposite sides of the technology box. This means that several technology boxes can be connected to a common central conditioning system can be connected, which means that fewer or no conditioning units may be required in the technology box (s).

For easy transport of the cultivation boxes and / or the technology boxes, it can be advantageous if one or more recesses for forks of an industrial truck are provided on a top side of the technology box provided for the arrangement of the cultivation box and / or that the technology box is designed as a transport pallet to be carried by a Industrial truck can be included.

The technology box preferably has a water tank and / or a water atomizer and / or a ventilation system and / or a control unit and / or a power connection and / or an electrical energy store and / or a ventilation flap. As a result, a self-sufficient conditioning system can be created with which conditioned air with the desired breeding conditions can be supplied to the breeding box or boxes. The ventilation system can optionally have a temperature control unit and / or the control unit can have a communication unit, wherein the communication unit preferably has a radio unit or is wired. This allows the temperature of the air supplied to be varied and the conditioning can be controlled remotely.

The technology box and / or the breeding box preferably have a sensor unit, the sensor unit preferably being a temperature sensor and / or humidity sensor and / or flow sensor and / or CO concentration sensor and / or vibration sensor and / or differential pressure sensor and / or visual sensor, preferably a camera , and / or has a position sensor. As a result, actual values of certain sizes can be measured and used for monitoring and, if necessary, for regulating the breeding conditions.

In the technology box, at least one operating medium container for an operating medium, preferably feed or additive, and a conveying system for conveying the operating medium into the breeding box are preferably provided, the conveying system preferably being pneumatic or mechanical. As a result, in addition to water, another resource can also be introduced into the cultivation boxes, which simplifies the automation of the cultivation.

It can be advantageous if a water supply connection connected to the water tank is provided on the technology box for connecting an external water supply and / or if an operating medium supply connection connected to the operating medium container is provided on the technology box for connecting an external operating medium supply. This means that manual refilling of the tanks is no longer necessary, which means that a higher degree of automation can be achieved. A water-permeable or water-storing material can also be provided in the breeding box, the material preferably comprising ceramic, gel, channels, capillaries or channels and / or at least one insert with a structure for laying eggs, pupating or hiding insects . This enables improved water storage and / or distribution and, by means of suitable structures, optimal conditions for the development of the insects can be created, for example for different types of insects.

A number of grow boxes are preferably stacked on top of one another on a technology box, so that the first and second supply air duct ends of the supply air ducts of adjacent cultivation boxes that face each other are connected so that the conditioned air can be fed from the technology box to the interior of the multiple grow boxes via the supply air ducts and the supply air openings. This means that several breeding boxes can be supplied from one technology box and a larger number of insects can be grown on the same area.

At least two stacks, each with at least one technology box and at least one cultivation box, can also be stacked on top of one another, the conditioned air being able to be supplied from one technology box to the at least one cultivation box arranged thereon. This means that several different breeding conditions can be created in one stack, which can be advantageous, for example, for the care of insects in different life stages.

In order to achieve a larger production volume, several stacks, each with at least one technology box and at least one cultivation box, are preferably arranged next to one another. It can be advantageous if the connection port of a technology box of a stack is connected directly or via a pipe connection to the connection port of a technology box of an adjacent stack and / or that the connection port of a technology box of a stack is connected to an external conditioning system. As a result, several stacks can be supplied with conditioned air in a simple manner from an external conditioning system. The technology boxes can, for example, only be provided to distribute the air and have fewer or no conditioning units of their own.

The present invention is explained in more detail below with reference to FIGS. 1 to 8, which show exemplary, schematic and non-limiting advantageous embodiments of the invention. It shows

1 shows the basic structure of the breeding system according to the invention,

2 shows an alternative structure of the breeding system according to the invention, Fig. 3 a breeding system with integrated air supply ducts,

Fig. 4 a breeding system with external air supply ducts,

5 shows a technology box in a preferred embodiment,

6 shows a cultivation system with several stacks arranged next to one another and an external conditioning system,

7a pressure conditions in a breeding system, and

7b pressure conditions in a breeding system with an exhaust air duct with a deflection device.

The basic structure of the modular breeding system 1 according to the invention is shown in FIG. The cultivation system 1 has at least one cultivation box 2 and at least one technology box 3. The cultivation box 2 and the technology box are designed in such a way that they can be stacked on top of one another to form a stack 4. In the example shown, e.g. several, in particular six, breeding boxes 2 are stacked on top of one another on a technology box 3. The breeding boxes 2 are provided for receiving and rearing insects and each have an interior space. In each of the cultivation boxes 2 e.g.

Insect eggs, insect larvae or already developed insects can be arranged. The breeding box 2 can also be equipped with a special insert that allows the insects to be efficiently grown in other stages of life or other insect species. This insert can also be connected to the infrastructure of the cultivation box 2 or to the technology box 3. The insert can, for example, have special channels that provide water directly to insects, such as beetles, to lay their eggs. The insert could also have special structures that favor oviposition or pupation. The insert can also have further inserts or be designed in such a way that it provides an optimized environment for the insects, for example in order to change or enlarge the surface or to offer the insects hiding places.

In order to ensure the most efficient possible rearing of the insects and thus the highest possible yield, it is necessary that predetermined breeding conditions exist in the breeding boxes 2. These include, for example, temperature, pressure, humidity and C0 ₂ concentration of the ambient air, amount of feed or an amount of a certain additive, etc. The technology box 3 is intended to supply at least one breeding box 2 with conditioned air in order to achieve these controlled breeding conditions and to be able to adapt individually if necessary. In the context of the invention, conditioned air is to be understood as meaning air, for example ambient air, with predetermined ambient conditions such as temperature, pressure, air humidity. the The air can be conditioned by a suitable conditioning system inside or outside the technology box 3, as will be explained in more detail below. In addition to the conditioned air, the breeding box (s) 2 can also be supplied with other operating media, such as feed or additives, for example by blowing or atomizing them into the air flow.

A stack 4, consisting of at least one technology box 3 and at least one cultivation box 2 arranged thereon, can for example be arranged on a transport pallet T, for example a known Euro pallet, as indicated in FIG. As a result, the stack 4 can be manipulated in a simple manner with an industrial truck such as a forklift truck and, for example, can be placed in a desired position in a high-bay warehouse. One or more recesses 21 for forks of an industrial truck can also be provided on an upper side of the technology box 3 on which the cultivation box 2 can be arranged. As a result, the one or more breeding boxes 2 can also be removed independently of the technology box 3 or placed on the technology box 3 and transported separately. This can be advantageous, for example, for filling the breeding boxes 2 with fresh insect larvae, insect eggs or for removing fully developed insects. The technology box 3 could of course also be combined with a transport pallet, for example designed as a transport pallet itself or connected to an existing transport pallet in order to be able to be picked up by an industrial truck. In this case, a separate transport pallet T would no longer be required.

As shown in FIG. 2, several stacks 4a, 4b each with at least one technology box 3 and at least one cultivation box 2 can be stacked on top of one another. The conditioned air and, if necessary, the additional operating resources can be supplied from one technology box 3 to the at least one cultivation box 2 arranged thereon. In the example shown, a cultivation box 2 is assigned to each technology box 3. In this way, for example, individual breeding conditions can be set in the two breeding boxes 2. This is advantageous, for example, when the insects in the breeding boxes 2 are in different stages of development or when different types of insects are being bred in the breeding boxes. As is also shown in FIG. 2, the technology box 3 can contain one or more components K of a conditioning system and / or an operating material supply system, as will be explained in more detail later.

According to the invention is on the technology box 3, preferably on the top, a

Outlet opening 5 is provided for the conditioned air and on the cultivation box 2 is a

Supply air duct 6 is provided, which is an underside of the cultivation box 2 with an opposite

Top of the cultivation box 2 connects, as can be seen in Figure 3 and Figure 4. The supply air duct 6 has a first open supply air duct end 6a on the underside of the cultivation box 2 and has on the top of the cultivation box 2, an opposite, second, open inlet air duct end 6b. A supply air opening 7 is provided on the supply air duct 6 between the supply air duct ends 6a, 6b and connects the supply air duct 6 to the interior of the cultivation box 2. The cultivation box 2 can be stacked on the technology box 3 in such a way that the outlet opening 5 of the technology box 3 is connected to the first inlet air duct end 6a of the inlet air duct 6 of the cultivation box 2, so that the conditioned air and, if applicable, added operating resources from the technology box 3 via the outlet opening 5 , the supply air duct 6 and the supply air opening 7 can be fed to the interior of the cultivation box 2.

As a result, a fluid-mechanical connection between the technology box 3 and the cultivation box 2 above it is established in a simple manner as soon as the cultivation box 2 is placed on the technology box 3. A flow cross-section of the supply air opening 7 is preferably smaller than a flow cross-section of the supply air duct 6, in that the supply air opening 7 is, for example, smaller than the width of the supply air duct 6. In the example according to FIG a fixed component of the cultivation box 2. This can mean, for example, that the supply air duct 6 is an integral part of the side wall and directly adjoins the inside or outside of the side wall of the cultivation box 2. In principle, however, the supply air duct 6 could also extend essentially tubularly between the bottom and the top of the cultivation box 2 through the interior of the cultivation box 2. In this case, the supply air duct 6 could be surrounded in the circumferential direction by the interior space and the first and second supply air duct ends 6a, 6b could also be spaced apart from the side wall.

The outlet opening 5 is arranged on the upper side of the technology box 3 so that it is essentially aligned with the first inlet air duct end 6a of the cultivation box 6 arranged thereon. In an advantageous embodiment, the supply air duct 6 can be designed, for example, as an interspace between a multi-walled, in particular double-walled, side wall of the cultivation box 2 and, for example, extend over part or substantially the entire width of the cultivation box 2. In this case, the air inlet opening 7 could be designed, for example, as a recess in the inner wall of the double-walled side wall adjoining the interior space. The air inlet opening 7 can, for example, be designed in such a way that the inner wall or at least a part of the inner wall has a lower height than the outer wall of the double-walled side wall that is opposite and adjoins the surroundings or than the two other adjoining side walls. In this case, the air inlet opening 7 is connected to the second air inlet duct end 6b.

As shown in FIG. 3, a plurality of cultivation boxes 2 can of course also be stacked on top of one another on a technology box 3 to form a stack 4 in such a way that first and second supply air duct ends 6a, 6b of supply air ducts 6 facing each other Adjacent grow boxes 2 are connected, in particular aligned, so that the conditioned air and possibly added equipment can be fed from the technology box 3 via the outlet opening 5, the supply air ducts 6 and the supply air openings 7 to the multiple cultivation boxes 2. With this modular structure, the cultivation system 1 can be easily expanded by stacking a desired number of identical cultivation boxes 2 on top of one another on a technology box 3. This can reduce the available capacity of the breeding system

1 can easily be adapted to a desired production quantity of insects. The cultivation boxes 2 can be designed, for example, as containers that are closed on all sides, preferably cuboid-shaped, the interior of which has only one supply air opening 7 and one exhaust air opening 8. For the introduction of insect eggs or larvae or for the removal of insects, a suitable opening can of course be provided which can be closed, for example, with a suitable cover. However, the cultivation boxes 2 are preferably designed in the form of an upwardly open, preferably cuboid-shaped container. In this case, a cultivation box 2 can be replaced by a cultivation box arranged above it

2 (see Fig. 1 + Fig. 3), by a technology box 3 arranged above (see Fig. 2) or by a closing element 23 (see Fig. 3), preferably airtight, be closable.

In an analogous manner, an exhaust air duct 8 (not shown in FIGS. 3 and 4) can optionally be provided on the cultivation box 2 (see FIGS. 7a + 7b), which connects the underside of the cultivation box 2 to the opposite top of the cultivation box 2 . The exhaust air channel 8 can have a first open exhaust air channel end 8a on the underside of the cultivation box 2 and can have an opposite, second open exhaust air channel end 8b on the upper side of the cultivation box 2. On the exhaust duct 8 between the exhaust duct ends 8a, 8b, an exhaust duct opening 9 is provided which connects the exhaust duct 8 with the interior of the cultivation box 2, so that used exhaust air can be discharged from the interior of the cultivation box 2 via the exhaust duct opening 9 and the exhaust duct 8 from the cultivation box 2. The exhaust air duct 8 is preferably arranged on a side of the breeding box 2 opposite the supply air duct 6. Here, too, a flow cross-section of the supply air opening 9 is preferably smaller than a flow cross-section of the exhaust air duct 8. The exhaust air duct 8 can be configured analogously to the supply air duct 6 and can for example be formed between a multi-walled, for example double-walled side wall (see above). A repetition is dispensed with at this point.

If the cultivation box 2 is made of plastic, for example, the supply air duct 6 and possibly the exhaust air duct 8 can be integrated, for example, directly into the wall of the cultivation box 2 during manufacture, for example by injection molding. This creates a robust and space-saving cultivation system 1. The supply air duct 6 and / or the exhaust air duct 8 can alternatively also be designed in the form of an external duct which is arranged on an outside of the cultivation box 2, for example can be plugged onto the cultivation box 2, as in FIG Fig.4 is shown. In this way, for example, existing breeding boxes 2 can be retrofitted with a supply air duct 6 and / or an exhaust air duct 8 according to the invention. In contrast to the embodiment according to FIG. 3, the outlet opening 5 is provided on the side of the technology box 3 here. The outlet opening 5 is connected with an L-shaped pipe section 10 to the first air intake channel end 6a of the air intake channel 6 of the breeding box 2 located above.

A closing element 23 is preferably also provided in the cultivation system 1, which can be arranged on the top of the cultivation box 2, in particular on the top of the topmost cultivation box 2 of a stack 4, in order to close at least the second inlet duct end 6b of the inlet air duct 6. Alternatively, the second supply air duct end 6b of the supply air duct 6 can also be designed to be self-closing. The closing element 23 can be designed, for example, in the form of a plate or a cover which can be arranged on the topmost cultivation box 2 of a stack 4, as indicated in FIG. 3 and FIG. The closing element 11 thereby closes at least the upper inlet air duct end 6b of the inlet air duct 6 of the uppermost cultivation box 2, which opens into the surroundings, preferably airtight, so that the conditioned air and possibly operating resources are not released into the surroundings in an uncontrolled manner.

If an exhaust duct 8 is provided on the cultivation box 2, then the closing element 23 can also be designed to close the second exhaust duct end 8b of the exhaust duct 8 so that used exhaust air is not released into the environment in an uncontrolled manner. If the cultivation box 2 is designed to be open at the top, then the closing element 23 can also be designed to close the entire cultivation box 2. In this case, the closing element 23 forms a wall or a cover of the top cultivation box 2. If the supply air duct 6 and / or the exhaust air duct 8 are designed to be self-closing, then a separate closing element 11 can also be dispensed with or the closing element 23 can be designed to close only the interior of the cultivation box 2. In the context of the invention, self-closing is to be understood as meaning that one or more suitable self-closing devices, such as flaps, valves, etc. are provided in the supply air duct 6 and / or exhaust air duct 8, which the first and / or second supply air duct end 6a, 6b or the Close the first and / or second exhaust air duct end 8a, 8b and only release it when there is contact with an adjacent cultivation box 2 or technology box 3.

In Figure 5, a technology box 3 is shown schematically in an advantageous embodiment.

In the example shown, a water tank 11, a water atomizer 12 and a ventilation system 13 are provided in the technology box 3 as components K of the conditioning system (see FIG. 3 + FIG. 4). Furthermore, there are one that has a communication unit

Control unit 14 and a power connection 15 are provided. Alternatively or additionally A suitable electrical energy storage device (not shown), such as a battery, for example, can also be provided for the power connection 15. The components K of the technology box 3 can be supplied with the necessary energy via the power connection 15 and / or via the energy store. The power connection 15 can, for example, also be designed in such a way that the technology boxes 3 of adjacent stacks 4 can be electrically connected so that the technology box 3 of one stack 4 can be supplied with energy from the technology box 3 of the other stack 4. The ventilation system 13, which can have a suitable fan, for example, is connected to the outlet opening 5 so that the conditioned air can be supplied to the cultivation box or boxes 2 with a certain predetermined or adjustable volume flow. The ventilation system 13 can thereby generate a controlled exchange between used exhaust air and supplied unused air. The exchange between used and unused air can be generated, for example, via a defined overpressure or underpressure in the cultivation boxes 2 with respect to the environment.

With the water atomizer 12, which can for example have a suitable pump, atomized water can be supplied from the water tank 11 to the air volume flow generated by the ventilation system 13. As a result, a desired humidity can be generated in the air flow that is fed to the breeding boxes 2, which is used to supply the insects with water. The ventilation system 13 and the water atomizer 12 can be activated by the control unit 14 in order to control the humidity and / or the volume flow and, if necessary, the temperature of the supplied air or preferably to regulate it to desired setpoints. The control unit 14 can be designed as suitable hardware and / or software, for example. A suitable memory unit can also be provided in the control unit 14, for example. Fixed, preprogrammed or variable time programs for the settings of the temperature, amount of air, amount of feed, amount of additive, humidity, etc. can be stored on the memory unit.

The water atomizer 12 is preferably activated in the form of a pulse during operation, so that the air humidity is changed alternately between a predetermined normal value and a predetermined pulse value that is higher relative thereto. The insect larvae can be irrigated by atomizing water into the air supplied. As a result, the humidity in the grow boxes is briefly raised to a very high value and, after the desired amount of water has been added, lowered again to the normal value. Through this pulsed control of the humidity, the insects can on the one hand be supplied with the desired amount of water, but on the other hand mold formation can be prevented by targeted drying phases in between. The filling of the water tank 11 with water and, if necessary, the filling of the Feed container with feed and / or the additive container with additive or other substances can take place within the framework of regular manipulation of the breeding boxes 2. The quantities should be large enough to guarantee the supply over a longer period of time.

In the ventilation system 13, a temperature control unit and / or a ventilation flap (not shown) can preferably also be provided, which can preferably also be controlled by the control unit 14. The ventilation flap can be provided in the area of the outlet opening 5, for example. As a result, the temperature and / or the pressure of the air volume flow can be controlled or preferably regulated to desired setpoints. In the context of the invention, the temperature control unit is to be understood as a device which is suitable for heating and / or cooling the air to a desired temperature. The temperature control unit can comprise suitable heating elements and / or heat exchangers, etc., for example. The ventilation system 13 can, for example, also be designed in such a way that it is suitable for removing and separating light materials, such as insect skins or dust, from the breeding boxes.

The communication unit of the control unit 14 can, for example, have a radio unit or can be wired. The wired communication can take place via the power connection 15, for example. Technologies known from the prior art can be used for the radio unit, such as WLAN, Bluetooth, etc. The control unit 14 of the technology box 3 can be controlled remotely during operation via the communication unit without direct access to the technology box 3 being required. This is particularly advantageous when the cultivation system 1 is used in a high-bay warehouse. The technology box 3 can be connected to a suitable power rail of the high-bay warehouse, for example, by means of the power connection 15. As a result, several technology boxes 3 can be centrally supplied with energy.

In addition to the water tank 11, equipment containers such as a feed container and / or an additive container as well as a suitable conveyor system for conveying the equipment to the breeding box 2 can also be provided in the technology box 3. The conveyor system can be designed pneumatically or mechanically, for example. It would be conceivable, for example, for the feed and / or the additive to be in liquid or water-soluble form or in powder form and, similar to the water, for example by atomizing or blowing it into the air stream. As a result, the feed and / or the additive can be fed to the breeding boxes 2 in a simple manner via the supplied air, without the need for separate lines. Optionally, however, a separate operating medium outlet opening could also be provided on the technology box 3 (analogous to the outlet opening 5) and operating medium ducts could be formed on the cultivation box or boxes 2 (analogous to the supply air ducts 6 and exhaust air ducts 8). As a result, the operating medium could be fed to the cultivation boxes 2 separately from the conditioned air. Furthermore, it can be advantageous if a water-permeable or water-storing material is provided in the cultivation box 2, the material preferably comprising ceramic, gel, channels, capillaries or grooves. As a result, the water supplied via the air flow can be stored and / or distributed in a suitable manner in the cultivation box 2 without the formation of mold.

As shown in FIG. 5, it can be advantageous if a sensor unit 16, which is connected to the control unit 14, is provided in the technology box 3. Alternatively or additionally, a sensor unit (not shown), which is connected in a suitable manner to the control unit 14 of the associated technology box 3, could also be provided in the cultivation box 2, for example in the supply air duct 6 or in the interior of the cultivation box 2. The connection can be established e.g. via suitable electrical contacts on the cultivation boxes 2 and the technology box 3 as soon as the cultivation box 2 is placed on the technology box 3. The sensor unit 16 of the technology box 3 and / or the breeding box 2 can for example have a temperature sensor and / or humidity sensor and / or flow sensor and / or CC> 2 concentration sensor and / or vibration sensor and / or differential pressure sensor and / or visual sensor.

With the sensor unit 16, actual values of the desired measured variables can thus be measured in order to detect a condition of the breeding environment. As a result, the breeding conditions can be monitored and the actual values can also be used, for example, for the preferred control or regulation of the breeding conditions by the control unit 14. In the context of the invention, a visual sensor is to be understood as meaning, for example, a suitable camera. The camera can for example be installed in the breeding boxes 2 in order to be able to visually monitor the condition of the insects. The differential pressure sensor can be used, for example, to regulate the air flow.

By means of the sensor unit 16, for example, the amount and the condition of the available feed can also be determined. This determination can, for example, via the

Measurement of the exhaust gas composition or by measuring the course of the

Humidity. The sensor unit 16 can, for example, also be a suitable one

Have sensor for measuring the condition or degree of maturity of the insect larvae. This can be done, for example, by measuring the CC> 2 concentration (with a CC> 2 sensor), by measuring the waste heat produced by the insect larvae (by a

Temperature sensor), by measuring the vibrations generated by the insect larvae (by means of a vibration sensor) or by measuring the reaction of the insect larvae to a stimulus such as watering (e.g. by optical detection of the movement by means of a camera or by measuring the humidity). The available components K of the technology box 3 (such as the ventilation system 13, the temperature control unit, the control unit 14 with optional communication unit, the sensor unit 16, the water atomizer 12, the conveying system for the equipment (e.g. feed, additive), the ventilation flaps or any other systems ) can be supplied with the necessary energy via the power connection 15 and / or via the electrical energy store.

Optionally, a water supply connection (not shown in FIG. 5) connected to the water tank 11 for connecting an external water supply can also be provided on the technology box 3. Alternatively or additionally, an operating medium supply connection connected to an operating medium container, such as the feed container or the additive container, for connecting an external operating medium supply can also be provided on the technology box 3. As a result, the water tank 11 and / or the operating medium container can be automatically refilled via a central supply system without each technical box 3 having to be filled manually. This embodiment is particularly advantageous when using the cultivation system 1 in a high-bay warehouse in which the technical boxes 3 are difficult to access. The central supply system can, for example, be part of the high-bay warehouse and have suitable lines that lead to the individual shelves.

A further advantageous arrangement of the modular breeding system 1 is shown in FIG. The cultivation system 1 has a plurality of stacks 4 arranged next to one another, each with at least one technology box 3 and at least one cultivation box 2. In the example shown, the stacks 4 are arranged in a shelf R of a high-bay warehouse. Two opposite connection ports 17 are provided on each of the technology boxes 3 for connecting an external conditioning system 18 and / or for connecting a further technology box 3. The connection connections 17 are preferably designed to be self-closing, so that they are closed when no technology box 3 or no external conditioning system 18 is connected and only open when a technology box 3 or an external conditioning system 18 is connected. The connection connections 17 could, for example, also be designed in such a way that the connection between the technical boxes 3 of adjacent stacks 4 is created automatically when the stacks 4 are appropriately placed on the shelf R, for example by means of suitable plug connections. The connection connections 17 can optionally also have sensors which check the quality of the connection. For example, a signal can be generated when an error condition, for example a leak, is detected. The stacks 4 can be positioned such that the connection port 17 of the technology box 3 of a stack 4 is connected directly or via a pipe connection 19 to the connection port of the technology box 3 of an adjacent stack 4 or to the external conditioning system 18. In the example shown, the external conditioning system 18 is integrated in the wall W of a building and connected to the technology box of the stack 4 adjoining it. The technology box 3 of the middle stack 4 is connected to the technology box 3 of the right stack 4 and the technology box 3 of the left stack 4 is in turn connected to the technology box 3 of the middle stack 4. The free connection port 17 of the technology box 3 of the left stack 4 is closed, preferably by a self-closing device, such as a flap or a valve.

The external conditioning system 18 can thus supply the technology boxes 3 of several adjacent stacks 4 with conditioned air and the conditioned air can be passed on to the cultivation boxes 2 as described from the technology boxes 3 via the supply air ducts 6 (not shown). Depending on how the external conditioning system 18 is specifically designed, it may be possible to dispense with certain components K in the technology boxes 3. In a simple embodiment of the external conditioning system 18, this can, for example, only provide an unconditioned air flow, so that no separate ventilation system 13 (see FIG. 5) is required in the technology boxes 3 or it can be deactivated. The setting of the available variables, such as temperature, air volume, air humidity and, if applicable, the amount of feed and / or amount of additive, etc., can also be done via the control unit 14 of the technology boxes 3. This is advantageous in order to enable different growing conditions in the individual stacks 4 despite the common central conditioning system 18. The setting of the variables by the control unit 14 can take place, as described, e.g. also as a function of the measured actual values of the available sensors of the sensor unit 16 in the form of a control or (feedback) regulation.

The sensor unit 16 can, for example, also have a position sensor for detecting a position of the technology box 3 in the high-bay warehouse. The setting of the available parameters (temperature, air volume, air humidity and, if applicable, amount of feed and / or amount of additive, etc.) can thereby also be changed as a function of the position on the shelf R, for example. This can be advantageous, for example, if several zones are defined in the high-bay warehouse for different stages of development of an insect species or for different insect species. Different settings of the breeding conditions can be defined for each zone. The control unit 14 of the technology box 3 recognizes the zone in which the respective technology box 3 is located and can automatically make the settings assigned to the respective zone for controlling the Use the available parameters (temperature, air volume, air humidity and, if necessary, amount of feed and / or amount of additive, etc.).

Used exhaust air can, for example, be discharged in an analogous manner via an external exhaust air connection (not shown) in the high-bay warehouse to a central exhaust air disposal system. A technical device for recovering thermal energy or moisture in the exhaust air disposal system can optionally also be provided, for example a heat exchanger or water separator. Alternatively or additionally, a technical device for removing unwanted odors or dust from the exhaust air, such as a filter or cyclone separator, could also be provided. If the cultivation boxes 2 do not have any exhaust air ducts 8, then the exhaust air could be fed to the external exhaust air connection, for example, directly from the individual cultivation boxes 2, for example via exhaust air openings 9 which are connected to a suitable collecting line. If the breeding boxes have 2 exhaust air ducts 8, the exhaust air of a stack 4 can e.g. also be taken from an open exhaust air duct end 8a, 8b (see e.g. Fig. 7a top right). However, it would also be conceivable for an inlet opening (not shown) (not shown) to be provided on each of the technology boxes 3 (analogous to the outlet opening 5), via which the exhaust air from the exhaust air ducts 8 of the cultivation boxes 2 located above is guided into the technology box 3. The technology boxes 3 of adjacent stacks 4 could in turn be connected to one another via suitable connection connections. As a result, the used exhaust air from several stacks 4 (in a manner analogous to the supplied conditioned air) could be discharged centrally via the technology box 3 of the respective last stack 4 to the central external exhaust air connection.

Of course, further or, in the extreme case, all of the components K required for conditioning the air could of course also be contained in the external central conditioning system 18. In this case, the technology boxes 3 could only serve to distribute the conditioned air and, if necessary, to add operating materials. In order to create the same pressure conditions in the stacks 4 as possible, it is advantageous if at least one ventilation flap is provided in each of the technology boxes 3 to control or regulate the air flow in the cultivation boxes 2, which is preferably arranged in the area of the outlet opening 5. It would furthermore also be possible for the technology boxes 3 of adjacent stacks 4 to be electrically connected via the respective power connections 15 (see FIG. 5). In this case, the energy supply could, for example, take place in the same way as the air supply centrally via a common external energy supply that is only connected to the technology box 3 of the right-hand stack 4. However, the necessary energy could also be made available, for example, via a power rail in the high-bay warehouse, to which each technology box 3 can be connected directly by means of the respective power connection 15. 7a shows a pressure distribution in three cultivation boxes 2a-2c arranged one above the other. The cultivation boxes 2a-2c are stacked as described, so that their supply air ducts 6 and exhaust air ducts 8 are fluidically connected as described. At the bottom left, an air stream L with a certain feed pressure pz is fed to the first air inlet duct end 6a of the air inlet duct 6 of the lowermost cultivation box 2c via the outlet opening 5 (not shown) of the technical box 3 shown in dashed lines. The air flow L flows via the air supply channels 6 through the air supply openings 7 into the interior of the breeding boxes 2a-2c. The second air intake channel end 6b of the air intake channel 6 of the upper cultivation box 2a is closed, for example self-closing or by the aforementioned closing element 11. The partial air flows LTa-LTc flow from the intake air openings 7 through the interiors of the respective cultivation box 2a-2c and via the exhaust air openings 9 in the exhaust ducts 8.

The partial air flows LTa-LTc are brought together again in the exhaust air ducts 8 to form an air flow L. The air flow L leaves the exhaust air duct 8 of the top cultivation box 2a through the upper, second exhaust air duct end 8b into the environment or, if necessary, to a connected exhaust air disposal system. The lower first exhaust duct end 8a of the exhaust duct 8 of the lowermost breeding box 2c is closed here, for example because the exhaust duct 8 is designed to be self-closing or because it is closed by the technology box 3 arranged below it. In the supply air duct 6 of the upper cultivation box 2a, there is a reduced supply pressure pz ‘due to the flow losses. This results in correspondingly different inlet pressures pza <pzb <pzc in the area of the air inlet openings 7 of the cultivation boxes 2a-2c. The pressure loss within the grow boxes 2a-2c is essentially the same, so that different outlet pressures paa <pab <pac result in the area of the exhaust air openings 9 of the grow boxes 2a-2c. In the exhaust air channel 8 of the upper cultivation box 2a, due to the flow losses, there is again a reduced discharge pressure pa ‘compared to the discharge pressure pa in the exhaust air channel 6 of the lowermost cultivation box 2c.

An alternative embodiment of the exhaust air ducts 8 is shown in FIG. In this case, a deflection device 20 for deflecting the air flow L is provided in the exhaust air ducts 8, so that a substantially U-shaped flow path of the air flow L results in the stacked state. In this case, the air flow L is discharged to the technology box 3 at the bottom right of the deflecting device 20, as indicated by the arrow, but could of course also be discharged to the environment. The cultivation boxes 2 are preferably designed identically. In this case, the deflection device 20 could arise, for example, in that the exhaust air duct 8 is formed by an at least three-walled side wall of the cultivation box 2. The deflection device 20 is thus formed by an intermediate wall arranged in the exhaust air duct 8 between the inner wall and the outer wall. As shown, the deflection in the flow path is preferably formed by a recess on the underside of the closing element 23. As an alternative to the deflection device 20, one or more baffle flaps (not shown) can also be provided for throttling the air flow L, which can be controlled, for example, via the control unit 14 of the technology box 3. As a result, the pressure gradient pa-pa ”in the flow path of the exhaust air ducts 8 can be adapted to a pressure gradient pz-pz 'in the flow path of the supply air ducts 6. This allows an im

Substantially the same pressure difference pza-paa = pzb-pab = pzc-pac can be achieved in each cultivation box 2a-2c, as a result of which the amount of air supplied in all cultivation boxes 2 is essentially the same.

Claims

Claims

1. Modular cultivation system (1) for insects with a cultivation box (2) for receiving and rearing insects and with a technology box (3) for supplying the cultivation box (2) with conditioned air, characterized in that the technology box (3) has a An outlet opening (5) for the conditioned air is provided that a supply air duct (6) is provided on the cultivation box (2) which connects an underside of the cultivation box (2) with an opposite upper side of the cultivation box (2), the supply air duct (6 ) has a first open supply air duct end (6a) on the underside of the cultivation box (2) and has an opposite, second open supply air duct end (6b) on the upper side of the cultivation box (2), that on the supply air duct (6) between the supply air duct ends (6a, 6b) an air inlet

(7) is provided, which connects the air inlet duct (6) with an interior of the cultivation box (2), and that the cultivation box (2) can be stacked on the technology box (3) in such a way that the outlet opening (5) of the technology box (3 ) is connected to the first end of the supply air duct (6a) of the supply air duct (6) of the grow box (2) so that the conditioned air from the technology box (3) via the supply air duct (6) and the supply air opening (7) to the interior of the grow box (2) is feedable.

2. Modular cultivation system (1) according to claim 1, characterized in that an exhaust air duct (8) is provided on the cultivation box (2) which connects an underside of the cultivation box (2) with an opposite upper side of the cultivation box (2), wherein the Exhaust air duct (8) on the underside of the cultivation box (2) has a first open exhaust air duct end (8a) and on the upper side of the cultivation box (2) has an opposite, second open exhaust air duct end (8b) that on the exhaust air duct (8) between the exhaust air duct ends (8a , 8b) an exhaust air duct opening (9) is provided, which connects the exhaust air duct (8) with the interior of the cultivation box (2), so that used exhaust air from the interior of the cultivation box (2) via the exhaust air duct opening (9) and the exhaust air duct (8) from the cultivation box (2) can be removed, the exhaust air duct (8) preferably being arranged on a side of the cultivation box (2) opposite the supply air duct (6).

3. Modular cultivation system (1) according to claim 1 or 2, characterized in that the supply air duct (6) is structurally integrated into the cultivation box (2) or is arranged in the form of an external channel on an outside of the cultivation box (2) and / or that the exhaust duct

(8) is structurally integrated into the cultivation box (2) or is arranged in the form of an external channel on an outside of the cultivation box (2), the structurally integrated supply air channel (6) and / or exhaust air channel (8) preferably through a multi-walled side wall of the Growing box (2) is formed.

4. Modular cultivation system (1) according to one of claims 1 to 3, characterized in that a deflecting device (20) or a damper for generating a pressure gradient is provided in the supply air duct (6) and / or in the exhaust air duct (8), the deflecting device (20) is preferably formed by an at least three-walled side wall of the cultivation box (2).

5. Modular cultivation system (1) according to one of claims 1 to 4, characterized in that a closure element (23) is provided in the cultivation system (1) which can be arranged on the top of the cultivation box (2) in order to surround the cultivation box (2) and / or to close the second supply air duct end (6b) of the supply air duct (6) and / or the second exhaust air duct end (8b) of the exhaust air duct (8) or that the supply air duct (6) and / or the exhaust air duct (8) are designed to be self-closing to to close the second inlet air duct end (6b) of the inlet air duct (6) and / or the second outlet air duct end (8b) of the outlet air duct (8).

6. Modular cultivation system (1) according to one of claims 1 to 5, characterized in that on the technology box (3) at least one, preferably self-closing, connection port (17) for connecting an external conditioning system (18) or for connecting a further technology box (3 ) is provided, with preferably at least two connection ports (17) being provided on opposite sides of the technology box (3).

7. Modular cultivation system (1) according to one of claims 1 to 6, characterized in that one or more recesses (21) for forks of an industrial truck are provided on an upper side of the technology box (3) provided for the arrangement of the cultivation box (2) and / or that the technology box (3) is designed as a transport pallet (T) so that it can be picked up by an industrial truck.

8. Modular cultivation system (1) according to one of claims 1 to 7, characterized in that the technology box (3) has a water tank (11) and / or a water atomizer (12) and / or a ventilation system (13) and / or a control unit (14) and / or a power connection (15) and / or an electrical energy store and / or a ventilation flap.

9. Modular cultivation system (1) according to claim 8, characterized in that the ventilation system (13) has a temperature control unit and / or that the control unit (14) has a communication unit, the communication unit preferably having a radio unit or being wired.

10. Modular cultivation system (1) according to one of claims 1 to 9, characterized in that the technology box (3) and / or the cultivation box (2) has a sensor unit (16), the sensor unit (16) preferably a temperature sensor and / or

Humidity sensor and / or flow sensor and / or CC> 2 concentration sensor and / or vibration sensor and / or differential pressure sensor and / or visual sensor, preferably a camera, and / or a position sensor.

11. Modular breeding system (1) according to one of claims 1 to 10, characterized in that in the technology box (3) at least one operating medium container for an operating medium, preferably feed or additive, and a conveyor system for conveying the operating medium into the breeding box (2) is provided, wherein the conveyor system is preferably designed pneumatically or mechanically.

12. Modular cultivation system (1) according to one of claims 8 to 11, characterized in that a water supply connection connected to the water tank (11) is provided on the technology box (3) for connecting an external water supply and / or that on the technology box (3) an operating medium supply connection connected to the operating medium container is provided for connecting an external operating medium supply.

13. Modular cultivation system (1) according to one of claims 1 to 12, characterized in that a water-permeable or water-storing material is provided in the cultivation box (2), the material preferably being ceramic,

Has gel, channels, capillaries or channels and / or that at least one insert with a structure for laying eggs, for pupating or for hiding insects is provided in the breeding box (2).

14. Modular cultivation system (1) according to one of claims 1 to 13, characterized in that several cultivation boxes (2) are stacked on top of one another on a technology box (3) to form a stack (4), so that first and second inlet duct ends (6a) facing each other , 6b) of the supply air ducts (6) of neighboring cultivation boxes (2) are connected so that the conditioned air can be fed from the technology box (3) via the supply air ducts (6) and the supply air openings (7) to the interiors of the several cultivation boxes (2).

15. Modular cultivation system (1) according to one of claims 1 to 13, characterized in that at least two stacks (4a, 4b) each with at least one technology box (3) and at least one cultivation box (2) are stacked on top of one another, the conditioned air from can each be fed to a technology box (3) of the at least one cultivation box (2) arranged thereon.

16. Modular cultivation system (1) according to one of claims 1 to 15, characterized in that several stacks (4) each with at least one technology box (3) and at least one cultivation box (2) are arranged next to one another.

17. Modular cultivation system (1) according to claim 16, characterized in that the connection port (17) of a technology box (3) of a stack (4) directly or above a pipe connection (19) is connected to the connection connection (17) of a technology box (3) of an adjacent stack (4) and / or that the connection connection (17) of a technology box (3) of a stack (4) with an external conditioning system (18) connected is.

18. Use of a modular breeding system (1) according to one of claims 1 to 17, for breeding insects, the following steps being carried out:

- Arranging at least one cultivation box (2) on a technology box (3) so that the outlet opening (5) of the technology box (3) is connected to the first inlet air duct end (6a) of the inlet air duct (6) of the cultivation box (2),

- Arranging insects, insect larvae or insect eggs in the at least one breeding box (2),

- Supply of conditioned air from the technical box (3) via the air inlet duct (6) and the air inlet opening (7) to the interior of the breeding box (2), the conditioned air preferably also containing an operating medium, in particular feed and / or additive.

19. Use according to claim 18, wherein the conditioned air supplied to the cultivation box (2) is conditioned in the technology box (3) or outside the technology box (3) to specified ambient conditions, preferably to a specified pressure and / or to a specified temperature and / or to a specified humidity.

20. Use according to claim 18 or 19, wherein the air humidity is changed alternately between a predetermined normal value and a predetermined pulse value which is higher relative thereto, in that the water atomizer (12) is controlled in a pulse-shaped manner by the control unit (14).