A cannabis growth support apparatus is provided. A cannabis growth support apparatus, for controlling one or more climate systems and monitoring growth of one or more cannabis plants coupled to one or more grow tents, comprising an enclosure housing said one or more climate systems coupled to a power source and a computing device. The computing device having a processor coupled to a computer memory and non-transitory computer readable media and a controller configured to power and regulate the one or more climate systems and a database, coupled to the computing device, for storing climate data from the one or more climate systems. The one or more climate systems is selected from the group consisting of a carbon dioxide enrichment and ventilation system, a humidifier, a dehumidifier, a heater and an air conditioning unit.

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.

A system for autonomous monitoring and/or optimization of plant (140) growth is provided. The system may include actuation devices configured to interact with an agricultural area (120), image sensors (130) configured to capture images (170) of a plant (140) in the agricultural area (120), and a processor (150) in communication with the image sensors (130) and the actuation devices. The processor (150) may be configured to store, via a memory (160), a first image (170) of the agricultural area (120) captured prior to a first actuation of the actuation devices; and trigger, synchronously with the first actuation, the image sensors (130) to capture a second image (180) of the agricultural area (120). The processor (150) may be further configured to detect features of the plant (140) in the first and second images (170) of the agricultural area (120); evaluate the detected features of the plant (140) for visual plant qualities (210); and dynamically set one or more parameters (190) of the actuation devices based on the visual plant qualities (210).

A plant cultivation apparatus is proposed. The plant cultivation apparatus of the present disclosure has a lighting module that is provided above a bed in a cabinet, and the lighting module includes a light source part including a plurality of light sources, a lighting case in which the light source part is provided, and a lighting cover coupled to the lighting case and covering the light source part. The lighting module is removably mounted to the cabinet in a removable manner.

A plant cultivation apparatus is proposed. The plant cultivation apparatus of the present disclosure has a lighting module that is provided above a bed in a cabinet, and the lighting module includes a light source part including a plurality of light sources, a lighting case in which the light source part is provided, and a lighting cover coupled to the lighting case and covering the light source part. The lighting module is removably mounted to the cabinet in a removable manner.

A multi-source ground-to-air heat transfer system is configured to store thermal energy during a cooling/dehumidifcation mode of operation for future use during a heating mode of operation. The multi-source ground-to-air heat transfer system utilizes a ground loop that is configured under an enclosure, such as a greenhouse, and is in thermal communication with a thermal reservoir medium to conduct and store heat. A thermal exchange fluid is pumped through the ground loop and ground heat exchanger and may receive heat from a condenser during a cooling/dehumidification mode of operation and may liberate heat to the evaporator during a heating mode. The enclosure air may receive heat from the heat pump during a heating mode and may liberate heat to the evaporator during a cooling/dehumidification mode. The heat exchange system may employ a heat pump having a reversing valve to change the mode of operation.

A lighting system for a vertical farm can include a plurality of modules configured to be stacked and removably coupled physically and electrically to one another by at least one overhead robot. Each of the plurality of modules can include at least one physical and electrical connector. At least some of the modules can include one or more lighting elements.

The present invention provides an intelligent cultivating system, which is used for monitoring and identifying a current cultivating status of a cultivating creature, and includes a processing center, a remote monitoring system and a harvesting system. The processing center is used for providing a cultivating regulation and controlling process for monitoring and identifying a current cultivating status. The remote monitoring system is used for regulating and controlling an automatic cultivating parameter of the cultivating regulation and controlling process. The harvesting system is used for preparing a dispatching process to the cultivating creatures, and used for collecting the automatic cultivating parameter of the cultivating regulation and controlling process.

A method to grow cannabis is described, wherein the method includes providing and treating a source of water, mixing the water with an additive to form a liquid mixture, transferring the liquid mixture to a plurality of cannabis plants grown in a growing medium including a mycorrhiza fungus, and growing the cannabis using a humidity control method, then harvesting the cannabis plants. Trimming and grinding the cannabis along with use of environmental control methods including temperature, humidity, lighting schedules, and carbon dioxide concentrations are also described.

A plant cultivating apparatus includes a body that defines a cultivation chamber, a cultivation bed disposed on the cultivation chamber and configured to move relative to the body, a nutrient storage configured to store nutrient solution, a pipe configured to supply the nutrient solution to the cultivation bed, a bed checker configured to detect movement of the cultivation bed, a level checker configured to detect a level of nutrient solution in the cultivation bed, and a controller configured to receive a signal from the bed checker and the level checker and to adjust the nutrient solution supplied to the cultivation bed. The cultivation bed includes a signal connector that is disposed on one surface of the cultivation bed corresponding to the bed checker and the level checker and that is selectively connected to the bed checker and the level checker according to whether to move the cultivation bed.