A control device controls a water supply device that supplies irrigation water to an open farm field in which a plant grows. The control device includes a storage unit, a calculation unit, and an output unit. The storage unit stores an environment value of each of a plurality of divided areas obtained by dividing the farm field and weather forecast of the farm field. The calculation unit calculates, based on an environment value and the weather forecast, an irrigation schedule in which supply time and amount of the irrigation water individually supplied to each of the plurality of divided areas during the irrigation period are determined. The output unit outputs to the water supply device, a control signal to control supply and no supply of the irrigation water to each of the plurality of divided areas based on the irrigation schedule.

A method and a system for growing plants on multilayer principle in mobile gutter farming is described, whereby, in the process of growing plants planted in cultivation gutters, said plants are conveyed in cultivation layers present on top of each other in a cultivation space in a longitudinal direction of the cultivation space in one or opposite directions. The cultivation gutters and the plants contained therein, are treated in the cultivation space by means of a processing arrangement in a cultivation layer-specific manner, whereby the cultivation gutters and the plants contained therein are first of all conveyed by motion elements in each cultivation layer of the cultivation space in the longitudinal direction of the cultivation space in opposite directions and are treated by processing elements in each cultivation layer of the cultivation space separately, in a manner substantially independent of the other cultivation layers.

A vegetation wall system includes an irrigation tank, a vegetation mounting unit with a vegetation holding unit, a pump feeding water from the tank to the holding unit, a programmable logic control unit including a central processing unit and a sensor, wherein the central processing unit monitors an aspect in the wall system by measuring, by the sensor, a component of the aspect as a first component measurement, waiting a predetermined period of time and then measuring, by the sensor, the component of the aspect as a second component measurement, determining, by the central processing unit, a change in the aspect based on the first and second measurements and the predetermined period of time, determining whether the change is outside a threshold range, in response to determining that the change is outside the threshold range, determining that an anomalous condition exists, and generating an alert when the anomalous condition exists.

A cultivation system for cultivating plants from e.g. seeds, seedlings, cuttings, etc. arranged in or onto substrate plugs (2), comprising a cultivation pot (1) having a bottom wall (4a), a side wall (4b) and filling channel (5) extending upwards from the bottom and/or side wall (4a 4b). Further comprising a filling module (6) provided with a filling connection (7) which is configured to cooperate with the filling channel (5) of the cultivation pot (1) for supplying the cultivation pot (1) with water. The cultivation system further comprises means for measuring the actual quantity of water or the actual water level in the cultivation pot (1), allowing control of the amount of water being supplied.

The present utility model provides an intelligent water supply seat for a planting pot, including a shell, a controller, a battery, a humidity sensor, a power source and a pipeline. The shell is internally provided with a water storage cavity. The controller and the battery are both installed in the shell and isolated from the water storage cavity. The humidity sensor is electrically connected with the controller and extends out of the shell. The power source is installed in the water storage cavity. The pipeline is connected with the power source and extends out of the shell. The controller is electrically connected between the battery and the power source. The humidity sensor is configured for detecting the humidity of soil in the planting pot on the intelligent water supply seat for the planting pot. The power source conveys water in the water storage cavity into the planting pot on the intelligent water supply seat for the planting pot through the pipeline.

The present utility model provides an intelligent water supply seat for a planting pot, including a shell, a controller, a battery, a humidity sensor, a power source and a pipeline. The shell is internally provided with a water storage cavity. The controller and the battery are both installed in the shell and isolated from the water storage cavity. The humidity sensor is electrically connected with the controller and extends out of the shell. The power source is installed in the water storage cavity. The pipeline is connected with the power source and extends out of the shell. The controller is electrically connected between the battery and the power source. The humidity sensor is configured for detecting the humidity of soil in the planting pot on the intelligent water supply seat for the planting pot. The power source conveys water in the water storage cavity into the planting pot on the intelligent water supply seat for the planting pot through the pipeline.

Disclosed are a plant growth management system and a control method thereof. A station device of the plant growth management system includes a flowerpot detector configured detect entry of a movable flowerpot device and to generate a detection signal according to whether entry of the movable flowerpot device is detected, a wireless charger configured to wirelessly supply power to the movable flowerpot device according to the detection signal, and a water supply device configured to supply water to a flowerpot included in the movable flowerpot device according to the detection signal, wherein the movable flowerpot device includes an obstacle detection sensor and a solar detection sensor, performs autonomous driving based on the obstacle detection sensor and the solar detection sensor, searches for a space, an illuminance value of which is equal to or greater than a preset illuminance value, through the autonomous driving, and performs rotational motion in the searched space.

A vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled lighting, airflow, humidity and nutritional support. The present disclosure describes a reciprocating cam mechanism that provides a cost-efficient mechanism for conveying vertical grow towers in the controlled environment. The reciprocating cam mechanism can be arranged to increase the spacing of the grow towers as they are conveyed through the controlled environment to index the crops growing on the towers. The present disclosure also describes an irrigation system that provides aqueous nutrient solution to the grow towers.

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.

The invention relates to a Novosphingobium sp. SJB007 and an application thereof in removal of phosphorus from wastewater, belonging to the technical field of environmental microorganisms. One aspect of the invention provides a Novosphingobium sp. SJB007 with an access number of CGMCC (China General Microbiological Culture Collection Center) No. 21177. Another aspect of the invention provides an application of the Novosphingobium sp. SJB007 in removal of phosphorus from wastewater. The efficient phosphorus-accumulating strain Novosphingobium sp. SJB007 provided by the invention has a high removal rate of more than 97% when the concentration of phosphorus in the wastewater is 10-30 mg/L under an appropriate condition.