An air flow system for a horticulture application is configured to facilitate simplified, reconfigurable air flow. Via use of adaptable and reconfigurable inlet ports, outlet ports, and a number and/or configuration of ventilation socks, the air flow system may be customizable to each respective application and/or produce increased plant density and/or health in horticultural applications.

A plant cultivation device may include a cabinet forming a space in which plants are cultivated: a door connected to the cabinet to open and close the space; at least one bed disposed in the space; at least one light assembly that irradiates light onto the at least one bed; a tank configured to store a fluid; a fluid supply module configured to supply the fluid to the at least one bed; and a sterilizer positioned outside of the tank and configured to sterilize the fluid within the tank.

In a method and device for cultivating a crop, cultivation takes place in an at least a substantially daylight-free, climate-conditioned cultivation space. The cultivation space extends between a first side and an opposite second side, wherein the crop is exposed to photosynthetically active radiation from an array of spatially separated artificial light sources. An airflow is guided over the crop from the first side to the second side. The artificial light sources are spatially distributed over the crop. Downstream light sources of the array of light sources produce a higher dosage of photosynthetically active radiation than light sources located further upstream as seen in the flow direction of the airflow guided over the crop.

The present invention relates to a system and method for farming. In particular, there is a system for indoor farming comprising at least one growth rack, the at least one growth rack comprises a plurality of cells; a plurality of farming modules, each farming module configured to be stored in a cell, each farming module configured to grow at least one type of plant; a machine arranged to move each of the plurality of farming modules in/from each of the corresponding cell; wherein each of the plurality of farming module comprises one or more self-contained nutrient tray portion specific to the type of plant, and wherein each farming module is independent with respect to other farming modules.

A method for the automated operation of a greenhouse which has at least one first plant growth room which is operated without artificial lighting and which has at least one second plant growth room which is different from the first plant growth room and which is equipped with artificial light sources for generating artificial light. An associated supply device and an associated greenhouse can be operated automatically.

Embodiments of the present disclosure provide an array of modularized circuits that work individually but collectively to provide a system that can manage an indoor environment. The system is designed in order to match the delivered load more closely to the required load then has been done in the past. The system is also designed in order to enhance and ease of serviceability of the individual circuits when needed.

Apparatus and methods for a hydroponics system with enhanced heat transfer are presented herein. By arranging the flow hydroponics system to have a series flow pattern via tubes and hydroponic pans, heat may be transferred from heat producing elements. The heat producing elements, including light emitting diodes (LEDs), may be thermally attached to the pans. The recycled heat can be transferred to the series circulating water supply for providing nutrient rich minerals at the roots of plants. Additionally, the heat can be transferred via the pans and without the need for costly fans or specialized heat sinks. In this way more space can be availed for the production of plants while recycling energy in the form of transferred heat.

Disclosed is an environment forming apparatus suitable for biological cultivation in extraterrestrial space. The apparatus includes a shell and a biological cabin configured in an upper space of the shell. A light management system for importing light of biological growth from external world is configured in the upper space, a thermal management system for at least balancing a temperature of the upper space and a water supplying system and configured for providing water for creatures growth are both configured on the shell. The biological cabin and the like are set at the appropriate part of the shell, an environment which is relatively suitable for biological growth or cultivation can be created and simulated on an extraterrestrial star, a condition is provided for ecological cultivation of the extraterrestrial space, an ecosystem of the extraterrestrial space can be formed, and a smooth extraterrestrial space biological experiment process is guaranteed.

An air flow system for a horticulture application is configured to facilitate simplified, reconfigurable air flow. Via use of adaptable and reconfigurable inlet ports, outlet ports, and a number and/or configuration of ventilation socks, the air flow system may be customizable to each respective application and/or produce increased plant density and/or health in horticultural applications. The ventilation socks may be disposed along rows of plants. The air flow system may be locally mounted to a scaffold system.

An air transport unit comprising a composite board. The composite board comprising an anode layer and a cathode layer of an electrically conducting material. The anode layer and cathode layer are separated by an insulator of an electrically insulating material. The composite board further comprising an electric component in electrical connection with the anode layer and the cathode layer. The air transport unit further comprising a carrier board, wherein the composite board and the carrier board each have a duct forming surface, which carrier board and composite board are arranged so that an air duct forms between the duct forming surfaces.