A method and system for supporting containerized plants in an upright and stationary position and at customizable, uniform spacing therebetween. The system comprises a frame, pockets, stabilizers positioned within the pockets and spacers. The pockets, stabilizers and spacers provide both horizontal and vertical support to each containerized plant, holding it securely in place without stakes or cables. The pockets with stabilizers and the spacers may be arranged in various patterns to promote stability of the system and health of the containerized plants. An irrigation system may be coupled to the system for maintaining and nourishing plants. The length of the frame is greater than the width, thus creating a stable environment to combat winds and disruptive forces. Individual frames may be attached to form designated and defined uniform growing or display areas and provide greater stability.

The present invention relates to an apparatus, system and method for monitoring plant. A sensor means can be adapted for receiving plant growth information of the plant being received inside a container. An indicating means can be adapted for indicating information of the plant growth information. A wireless communication means can be adapted for transmitting the plant growth information to an external device. A control means can select a working mode of the indicating means and the wireless communication means. Through the cooperative effect of the sensor means, the storage means, the indicating means and the wireless communication means, operators do not have to take along with instruments to perform measurement reading of the on-site plant growth information at a regular time, thereby saving labor cost and time cost of monitoring the plant growth information and improving efficiency of plant monitoring.

The disclosure relates to a plant growth apparatus and related system to grow and maintain plants under controlled biotic conditions, for example to grow axenic (microbe-free) plants, gnotobiotic (defined microbiota) plants, and holoxenic (complex, or undefined microbiota) plants. This system allows aseptic bottom irrigation with water, soluble nutrients, chemicals, and/or microbiota. Plants can be inverted for dipping and/or vacuum infiltration. The system also allows for passive (gravity) drainage, thereby allowing for gas exchange and preventing root anoxia. A variety of plant growth substrates can be used within the plant growth apparatus as a plant growth medium. The plant growth apparatus, containing the growth substrate medium, can be completely flushed via the drainage port to remove potential toxic byproducts of the sterilization processes. The entire system is suitably constructed using autoclavable material.

A photobioreactor for cultivating photoautotrophs that comprises a first hatcher for containing the photoautotrophs and a first feed medium; a second hatcher for holding the photoautotrophs and a second feed medium; and a pump connected to the first hatcher, the second hatcher or both the first hatcher and the second hatcher for moving the photoautotrophs between the first hatcher and the second hatcher or vice versa.

A novel collapsible plant support includes a collapsible coil adapted to rest on a flat surface. In a particular embodiment, the collapsible plant support includes a plurality of vertical support structures coupled to the collapsible coil so as to provide additional support. In another particular embodiment, a collapsible plant support includes plant receptacle receiving element that supports both a collapsible coil and also a plant receptacle. In a more particular embodiment, the plant receptacle receiving element includes fluid ducts for connecting multiple plant receptacle receiving elements into a fluid network. In another embodiment, the coil is disposed within a helical sleeve coupled to a flexible, cylindrical mesh.

The present invention relates to both a device and a system for monitoring plants and providing advice to a plant grower for optimizing indoor and outdoor plant growth. The device is packaged within a natural housing to promote a natural and pleasing appearance blending with the plant environment. With respect to the device, the core components are a probe comprising the plurality of environmental sensors, a microcontroller, a communication device, and a power source. With respect to the system, it is best characterized as a connected architecture capable of remotely exchanging information among the probe, a mobile device, a mobile app, a plant profile, a decision engine, a network, a remote computer, and a plant profile database. This system captures the target plant's current environmental conditions from the probe in real-time, compares the environmental conditions with the optimal parameters in the plant profile, and provides timely plant growth advice, where the latter is accomplished via a local alert or remotely via a mobile device.

Provided is a plant cultivation device wherein the occurrence of tipburn is suppressed. This artificial light-type plant cultivation device 1 is provided with a cultivation chamber 4, the inside of which can be sealed. Within the cultivation chamber 4, the plant cultivation device is provided with: a cultivation room 10 for growing a plant; and an air circulation system 30 for generating an air flow from top to bottom in the cultivation room 10. Since the air circulation system 30 can blow air to a plant V from directly above, air is blown to new leaves growing in a central portion of the plant to promote transpiration. As a result, sufficient calcium can be supplied to the growing leaves and tipburn is less likely to occur.

A fastener device adapted for attaching at least one tag (or other identifier) to an object. The fastener device comprises a T-bar component, a paddle component, and a filament component flexibly attached to both the T-bar component on one end and the paddle component on the other end. In some embodiments, the fastener device is deployable via a fastener dispensing device comprising a needle designed to puncture a hole in at least one tag and the object while also inserting the T-bar component through the hole. Once inserted, the paddle component exerts a cantilever spring force against at least one tag holding the tag(s) securely against the object.

A method for tracking seeds in an assembly line grow pod having a plurality of carts is provided. A target seed is deposited in a selected cell which is a part of a selected tray located in a selected cart travelling on an assembly line grow pod. A position of the target seed is tracked in the selected cell by determining the position of the target seed in the selected cart and determining a position of the selected cart in the assembly line grow pod. Sustenance is provided to the target seed including the selected cell. A growth factor of the target seed is determined in the selected cell. Upon determination that the growth factor of the target seed in the selected cell is below a predetermined threshold, supply of the sustenance provided to the selected cell is adjusted.

Generally described, a growing container for a vertical rack system includes an inner container portion with a plurality of inlet perforations across a sidewall, an opening for plant growth, and a base panel with a plurality of outlet perforations. An outer container portion is configured to at least partially surround the inner container portion, and having a fluid inlet port and a fluid drain port. An upper seal and a lower seal are disposed between the inner container portion and the outer container portion on either side of the plurality of inlet perforations to allow a fluid from the fluid inlet port to cover the plurality of inlet perforations at any tilt angle of the growing container. The fluid drain port allows excess fluid drainage. A racking handle protrudes from the outer container portion with an internal angle corresponding to the tilt angle when coupled to a vertical rack system.