An ecological cultivation system with a high pressure fine water mist. A nutrient solution supply system and a cultivation frame, a root of a crop seedling being wrapped within a planting sponge body, a planting sponge body being fixed on the cultivation frame, a nutrient solution supply system including a nutrient solution storage tank, a filter, a magnetizer, a low pressure ball valve, a high pressure pump, a high pressure ball valve, and a high-pressure fine water mist sprayer, a liquid outlet of a nutrient solution storage tank being connected to a water inlet of the high pressure pump by a filter, a magnetizer, and the low pressure ball valve being connected in series, and a water outlet of the high pressure pump being connected by the high pressure ball valve, to the high-pressure fine water mist sprayer provided within the cultivation frame.

A problem to be solved by the present invention is to obtain a nutriculture system that can manage a growth environment of a plant in accordance with the state of the plant, to thereby produce good quality vegetables and fruits with low production costs. The nutriculture system (100) of the present invention is a nutriculture system for cultivating plants (10) using a nutrient solution (L). The nutriculture system comprises: a growth section (110) configured for growing the plants; a nutrient solution tank (131) configured for containing the nutrient solution; a measurement section (140) configured for measuring the concentration of at least one of a plurality of ions contained in the nutrient solution; and a control section configured for controlling the growth environment of the nutriculture system based on change in a measured value of the ion concentration.

An automated plant cultivation system is provided having multi-tiered vertically arranged horizontal magazine structures each employing seed or plant capsules with a fluid circulation and illumination and communication network controlled by an on-board processor. Particularly, the system includes a magazine structure having seed/plant capsules within seed/plant reservoirs alternately arranged between at least one of a light source substantially concealed from direct viewing. A fluid channel extends across a long axis of the magazine structure, wherein the magazine structure is adapted for use of seed/plant capsules with nutrient composite plant growth cultivation, hydroponic plant growth cultivation, aeroponic plant growth cultivation methods or combinations thereof.

Growing systems may include a number of modular growing chambers adapted to be configured in a stacked arrangement with each growing chamber surrounding a corresponding portion of the plant. The grow chambers may be selectively added or removed during plant growth, such that different sections of the growing plant may be influenced differently using aeroponic, hydroponic or other growing techniques. The grow chamber stack may be portable and provided with integrated or independent lifting devices to assist an operator in adding or removing chambers from the stack. Three growing processes may be facilitated using such systems. These include a process for producing assorted product from a single plant for simultaneous harvest, a process for producing an extended harvest of a desired size product from a single plant, and a process for extending the productive life of a plant and provide for multiple, continued, and perpetual harvest.

An aquaponic grow system includes a plurality of sensors for sensing nutrient levels in liquid provided to a grow chamber, and to adjust nutrient levels based on the sensed levels. In some embodiments the system includes a plurality of sensors configured to sense nutrient levels in a common chamber, with the system configured to calibrate the sensors.

A bioreactor includes a bioreactor container, and a root stand. The container has a base and one or more sidewalls connected to the base, the base and sidewalls together defining an interior bioreactor volume. The root stand is supported by the container within the bioreactor volume, and includes a first support comb and a second support comb, each support comb having a plurality of spaced apart teeth. The teeth of the first support comb extend in length in a first direction and the teeth of the second support comb extend in length in a second direction different from the first direction. The first support comb overlaying the second support comb when the root stand is supported in the container, and the first support comb being separable from the second support comb when the root stand is removed from the container. A gravity well and atmosphere control container are also disclosed.

Methods are proposed to define UE behavior for performing synchronization signal block (SSB) based radio link monitoring (RLM) and channel state information reference signal (CSI-RS) based RLM. In a first novel aspect, if CSI-RS based RLM-RS is not QCLed to any CORESET, then UE determines that CSI-RS RLM configuration is error and does not perform RLM accordingly. In a second novel aspect, SSB for RLM and RLM CSI-RS resources are configured with different numerologies. UE perform SSB based RLM and CSI-RS based RLM based on whether the SSB and CSI-RS resources are TDMed configured by the network. In a third novel aspect, when multiple SMTC configurations are configured to UE, UE determines an SMTC period and whether SMTC and RLM-RS are overlapped for the purpose of RLM evaluation period determination.

Described herein are example portable indoor hydroponic garden assemblies and associated methods of use. The portable indoor hydroponic garden assemblies can include features that facilitate hydroponic gardening in an indoor environment, including structural features that enhance the indoor environment itself, such as through sounds, smells, textures, sights, and so on. In an example, the portable indoor hydroponic garden system includes a tiered growing assembly housed fully within an enclosure. The tiered growing assembly can include a group of trays defining tiers that are recessed from one another, allowing water or other fluid to flow from tray to tray, creating waterfall features there between that can aerate the water and emit a pleasurable sound to the indoor environment. The enclosure can be climate controlled and thus adaptable to a variety of indoor conditions to grow desired plants, including embodiments using programmable heating and lighting systems.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module mounted within the grow chamber for receiving a plurality of plant pods. A motor rotates the grow module between a plurality of angular positions and a camera system captures images of the plants at the various positions. The plurality of images are used by the controller to estimate a total plant mass or a total plant volume, or the controller may stitch together the plurality of images to generate a 3D image that may be used to detect abnormal growth conditions or otherwise provide feedback to a user.

A hydroponic plant growth system including an upwardly extending housing having a cavity therein defining a liquid nutrient flow column and a plurality of growth pod ports each extending from a respective port opening at an outer surface of a front wall of the housing to the cavity. Each growth pod port sized to receive a growth pod. Wherein when a growth pod is mounted in a respective one of the growth pod ports, a mounting flange of the growth pod abuts the outer surface the front wall and a growth pod axis of the growth pod extends downwardly from a respective growth pod proximal end through the growth pod port at an angle of between 30 degrees and 60 degrees to the growth pod port axis.