Embodiments herein disclosed relate to a computer-controlled germination system built around a rotating vessel within which a germinating process takes place. The system includes automatable controls over air flow, water flow, temperature, and vessel rotation; and air and water recirculation mechanisms provide energy efficient control over air and water temperature, humidity, and/or CO.sub.2 content.

Invention is the innovative apparatus to determine plant seeds quality rate in a dormant stage. Aim of the invention is measuring quantity of carbon dioxide radiance on active seeds to calculate average of the germination, the vigor, and a proportion of the value of the light radiated seeds to calculate viable. Apparatus use process of the spectral lighting to warm up seeds to obtain thermal contrasting Infra-red images, to visualize seeds embryos metabolism. The contingent seeds embryos intensity of the radiance is taken in account to determine seeds measurement of the viability, of the vigor indicative. Due to order to create the specimen seed embryo radiometric profile data, recording digital images of the seed unit's specimen data enable to derive, and then calculate the Infra-red contrast value of seed specimen profile. Light titrations of the seeds thermal exposition, due to seeds specimen rotation, eliminate irregularity of the seed layer lighting.

Containers for growth of sprouts are described. The covered containers have an air-permeable seal and may also have additional openings to increase the air permeability rate of the covered container. The air permeability rate is balanced to have sufficient air exchange but with an evaporation rate that is low enough to avoid addition of water during germination and growth of the cryo-sprouts. The seeds and sufficient water are added to the container and covered with a lid to form an air-permeable covered container. The seeds germinate and grow in the covered container at pathogen antagonistic temperature without the removal of the lid until use by consumer. This results in cryo-spouts in that have reduced numbers of pathogenic organisms, are greener and have an extended shelf-life.

Containers for growth of sprouts are described. The covered containers have an air-permeable seal and may also have additional openings to increase the air permeability rate of the covered container. The air permeability rate is balanced to have sufficient air exchange but with an evaporation rate that is low enough to avoid addition of water during germination and growth of the cryo-sprouts. The seeds and sufficient water are added to the container and covered with a lid to form an air-permeable covered container. The seeds germinate and grow in the covered container at pathogen antagonistic temperature without the removal of the lid until use by consumer. This results in cryo-spouts in that have reduced numbers of pathogenic organisms, are greener and have an extended shelf-life.

A system for germinating seeds according to a germination recipe is disclosed. The system for germinating seeds for a grow pod includes a plurality of germination sub-tanks configured to receive seeds, the plurality of germination sub-tanks receiving different species of seeds, respectively, a master germination tank configured to receive seeds from one or more of the plurality of germination sub-tanks, and a controller. The controller includes one or more processors, one or more memory modules storing germination recipes, and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the controller to: determine a ratio of the different species of seeds based on a germination recipe, operate the plurality of germination sub-tanks to provide seeds to the master germination tank based on the ratio, and provide the seeds in the master germination tank to one or more carts.

A system for an assembly line grow pod includes a germination hub including a tank, a water source in selective fluid communication with the tank, a pump in selective fluid communication with the tank and the water source, a pod line in selective fluid communication with the germination hub, a seeder assembly in selective fluid communication with the pod line, the seeder assembly including a seeder tank, and a metering device in selective fluid communication with the seeder tank, where the metering device selectively releases seeds from the seeder tank, and a cart positioned below the metering device.

A method for wetting seeds for an assembly line grow pod includes positioning a first batch of seeds within a tank, directing water from a water source to the tank through a lower portion of the tank, wetting the first batch of seeds within the tank with the water from the water source, initiating germination of the first batch of seeds, draining the water from the tank after a predetermined submersion time, subsequent to draining the water from the tank, directing water from the water source to the tank through the lower portion of the tank, wetting the first batch of seeds within the tank with the water from the water source for the predetermined submersion time, and releasing the first batch of seeds from the tank to a pod line in fluid communication with an assembly line grow pod after a predetermined time.

A method for wetting seeds for an assembly line grow pod includes positioning a first batch of seeds within a tank, directing water from a water source to the tank through a lower portion of the tank, wetting the first batch of seeds within the tank with the water from the water source, initiating germination of the first batch of seeds, draining the water from the tank after a predetermined submersion time, subsequent to draining the water from the tank, directing water from the water source to the tank through the lower portion of the tank, wetting the first batch of seeds within the tank with the water from the water source for the predetermined submersion time, and releasing the first batch of seeds from the tank to a pod line in fluid communication with an assembly line grow pod after a predetermined time.

A method for moving wetted seeds from a tank includes positioning a first batch of seeds within a tank, directing water from a water source to the tank, wetting the first batch of seeds within the tank with the water from the water source to initiate germination of the first batch of seeds, releasing the first batch of seeds from the tank to a pod line in fluid communication with an assembly line grow pod after a predetermined time, and subsequent to releasing the first batch of seeds from the tank, detecting a level of seeds remaining in the tank.

A method for pumping seeds to an assembly line grow pods includes releasing seeds to a pipe in fluid communication with a pump, moving water from a water source to the pipe in fluid communication with the pump, combining the seeds released from the tank with the water from the water source in the pipe, and pumping the combination of the seeds released from the tank and the water from the water source to a grow pod line in fluid communication with the pump, and moving the seeds from the grow pod line to one or more carts of an assembly line grow pod.