Abstract: Disclosed herein are bed seed holders and assembly line grow pods incorporating bed seed holders for growing plants. According to some embodiments, a bed seed holder includes a body having an elevation envelope, at least one seed receptacle extending into the body, where the seed receptacle is adapted to maintain a fluid within the seed receptacle, and a spigot that is adapted to maintain a level of the fluid within the body below the elevation envelope.

Abstract: A method for applying recipes in a plurality of grow pods includes receiving a first modified recipe from a first grow pod, the first grow pod including a first physical parameter, receiving a second modified recipe from a second grow pod, the line grow pod including a second physical parameter that is different than the first physical parameter, receiving a request from a third grow pod for a modified recipe, determining that the third grow pod includes the first physical parameter or the second physical parameter, in response to determining that the third grow pod includes the first physical parameter, implementing the first modified recipe at the third grow pod, and in response to determining that the third grow pod includes the second physical parameter, implementing the second modified recipe at the third grow pod.

Abstract: Systems and methods for providing an assembly line grow pod are provided. One embodiment of a grow pod includes an exterior enclosure that defines an environmentally enclosed volume, a track that that is shaped into a plurality of helical structures defining a path, and a cart that receives a plant and traverses the track. Some embodiments include a sensor for determining output of the plant, a plurality of environmental affecters that alter an environment of the environmentally enclosed volume to alter the output of the plant, and a pod computing device that stores a grow recipe that, when executed by a processor of the pod computing device, actuates at least one of the plurality of environmental affecters. In some embodiments, the grow recipe alters a planned actuation of the at least one of the plurality of environmental affecters in response to data from the sensor indicating a current output of the plant.

Abstract: Embodiments disclosed herein generally relate to systems and methods for emptying and/or cleaning a tray within in an assembly line grow pod. In one embodiment, a sanitizer component for cleaning a tray coupled to a cart in an assembly line grow pod is disclosed. The sanitizer component is coupled to a track such that the cart and the tray are received in the sanitizer component via the track. The sanitizer component comprises a first actuator arm positioned underneath the track and extendable through an opening in the track and an aperture at a bottom end of the cart to contact the tray such that the tray rotates in a first direction. The sanitizer component further includes an actuator motor coupled to the first actuator arm for extending the first actuator arm and a controller. The controller is communicatively connected to the actuator motor in the sanitizer component.

Abstract: A cart having a wheel, a drive motor coupled to the wheel such that an output of the drive motor causes the wheel to rotate and propel the cart, a cart-computing device communicatively coupled to the drive motor; and one or more sensors communicatively coupled to the cart-computing device, the one or more sensors generating one or more signals in response to a detected event. The cart-computing device receives a communication signal and electrical power via the wheel. The communication signal corresponds to one or more instructions for controlling an operation of the cart. The cart-computing device receives the one or more signals from the one or more sensors. The cart-computing device generates and transmits a control signal to the drive motor to cause the drive motor to operate based on at least one of the one or more signals generated by the one or more sensors or the communication signal.

Abstract: Systems and methods for operating a grow pod are provided herein. One embodiment of a system includes a cart that moves on a track of the grow pod, where the cart receives a seed for growing into a plant. The system may also include a human-machine interface (HMI) that is coupled to the grow pod and a pod computing device coupled to the HMI. The pod computing device stores logic that, when executed by the pod computing device, causes the system to receive a grow recipe for the seed in the cart, wherein the grow recipe includes actuation of at least one environmental affecter and provide a user option to alter functionality of the grow recipe. In some embodiments, the logic may also cause the system to receive a user selection of the user option and in response to receiving the user selection, alter functionality of the grow recipe.

Abstract: A light control system includes a lighting device, a cart configured to move along a track under the lighting device, and a controller. The controller includes a processor a memory module storing lighting recipes, and machine readable instructions stored in the memory module that, when executed by the processors, causes the controller to identify a plant in the one or more carts, retrieve a lighting recipe for the identified plant from the one or more memory modules, and control operations of the one or more lighting devices based on the lighting recipe for the identified plant.

Abstract: A system for utilizing waves in an assembly line grow pod includes a plurality of carts, a wave generator and a master controller. The plurality of carts carries a plurality of plants including a first plant and a second plant. The wave generator generates sound waves having a different range of frequency. The master controller is communicatively coupled to the wave generator and comprising a processor and a memory storing a wave recipe and instructions. The wave recipe correlates the plurality of plants with different characteristics of sound waves including frequency. The wave generator generates a first sound wave having the characteristic correlated to the first plant and a second sound wave having the characteristic correlated to the second plant.

Abstract: A track system for a cart includes a plurality of curved modular track sections for the cart. Each of the plurality of curved modular track sections includes one or more rails configured to engage with the cart on the track, and one or more reservoir sections configured to receive liquid from the cart. Each of the plurality of curved modular track is tilted relative to ground by a predetermined angle such that the one or more reservoir sections are configured to direct the liquid to a predetermined area. Each of the plurality of curved modular track sections includes a gear system configured to engage with a gear of the cart.

Abstract: A temperature control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more vents connected to the air supplier and configured to output air within the enclosed area, and a controller. The controller includes one or more processors, one or more memory modules, 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: identify a plant on the one or more carts, determine a temperature recipe for the identified plant, and control a temperature of the air output from the one or more vents based on the temperature recipe for the identified plant.

Abstract: Assembly line grow pods that include watering stations positioned to provide water plant material at predetermined days of growth and methods of supplying the same are disclosed. An assembly line grow pod includes a track extending a length between a seeder component and a harvester component, a plurality of watering stations arranged adjacent to the track at a plurality of locations along the length of the track between seeder and harvester components, and a cart supported on and movable along the track from the seeder component to the harvester component such that seeds that are placed by the seeder component within the cart grow into plant material that is harvested at the harvester component. Each one of the plurality of watering stations is positioned between the seeder and harvester components such that water is provided by the watering station to the cart at a predetermined growth metric.

Abstract: Systems and methods for determining harvest timing for a cart within an assembly line grow pod include identifying a type of the plant matter positioned within a cart, detecting at least one of a plant matter weight of the plant matter with a weight sensor, a plant matter height of the plant matter with a distance sensor, and a chlorophyll level of the plant matter with a camera, determining that the at least one of the detected plant matter weight, the detected plant matter height, and the detected chlorophyll level satisfies a harvest time parameters, and in response to determining that the detected plant matter weight, the detected plant matter height, and the detected chlorophyll level satisfy the harvest time parameters, directing the cart to a harvester system.

Abstract: An air flow control system for an assembly line grow pod is provided. The air flow control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more outlet vents coupled to the air supplier, and a controller. The controller includes one or more processors, one or more memory modules, 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 identify a plant on the one or more carts, determine an airflow rate based on an airflow recipe for the identified plant, and control the air supplier to output air through the one or more outlet vents at the airflow rate.

Abstract: A molecular air control system is provided. The system includes a shell including an enclosed area, a cart moving on a track within the enclosed area, an air supplier configured to output air into the enclosed area, and a controller. The controller includes one or more processors, one or more memory modules, 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: identify a plant on the cart; determine a target carbon dioxide concentration level for the identified plant based on a molecular recipe for the identified plant; receive a current carbon dioxide concentration level from a carbon dioxide sensor; compare the target carbon dioxide concentration level with the current carbon dioxide concentration level; and adjust carbon dioxide concentration level of the air output from the air supplier based on the comparison.