The invention relates to a planting method of DendrobiumnobileLindl, it comprises the following steps: Selecting betel palm trees that are more than 5 years old or or more than 6 meters high; Selecting the DendrobiumnobileLindl seedlings with a height of more than 12 cm, with 1 or 2 new buds and complete roots, stems and leaves, and dividing DendrobiumnobileLindl seedlings into 2-4 clumps a group; Combing and aligning the roots of each group of DendrobiumnobileLindlseedlings, taking one group of DendrobiumnobileLindl seedlings and sticking them to the knot of the betel plain tree each time, then using a cotton rope or a tie to wind and fix the DendrobiumnobileLindl seedlings on the betel palm tree trunk from the stems of each group of DendrobiumnobileLindl seedlings; Putting the roots below the stembase of the DendrobiumnobileLindlseedling on the betel palm tree trunk and smearingdendrobium nutrient. It solves the technical problem that the trunks and branches of the tree species selected by the existing methods of planting by sticking trees are not flat enough, it is not easy to fix the Dendrobiumnobile seedlings, and at the same time, it is necessary to destroy the trees planted with dendrobium and cause damage to the trees.

The object of the invention is a plant cultivation container, wherein the plants do not need to be transplanted during cultivation or growth. The container is provided with pull-out trays and this allows continuous adaptation of the container volume to the growth and development of the root system. The container of the invention provides for continuous oxygen and air supply to the root system and for development of fibrous roots contrary to root spiralisation which is typical of conventional containers. The pull-out tray has several functions: partitioning of container volume to compartments, retaining of excess water while watering, and as a drip tray when the entire container volume is in use. The walls of the container are provided with notches at various heights which in conjunction with several pull-out trays partition the entire volume of the container along its height to several compartments. The notches are sized in a way to adapt to the thickness and height of the side walls and the bottom of a pull-out tray when the trays are inserted into the notches. The pull-out trays are simply insertable into and removable from the notches and this is why the container volume can simply be adapted to the growth and development of the root system.

Embodiments of the present invention are related to a tree rooting enclosure apparatus including a body with a cylindrical body base and a pair of opposing tapered ends culminating into a pair of opposing end openings. The body may include a plurality of longitudinal channels extending the length of the cylindrical body base. The apparatus as a whole may be comprised of two removably engaged halves forming a water-resistant fit.

A tree rooting enclosure apparatus including a body housing with a cylindrical body base culminating into a pair of opposing end openings. The body and end openings are structured to accommodate a portion of a plant therethrough. The apparatus as a whole may be made of two removably engaged elongate halves structured to surround a selected portion of a plant and attach to itself forming a water-resistant fit around the selected portion of the plant.

A tree rooting enclosure apparatus including a body housing with a cylindrical body base culminating into a pair of opposing end openings. The body and end openings are structured to accommodate a portion of a plant therethrough. The apparatus as a whole may be made of two removably engaged elongate halves structured to surround a selected portion of a plant and attach to itself forming a water-resistant fit around the selected portion of the plant.

A plant growing system configured for high density crop growth and yield, including an environmentally-controlled growing chamber and a vertical growth column within, the column configured to support a hydroponic plant growth module which is configured for containing and supporting plant growth media for containing and supporting a root structure of at least one gravitropic crop plant growing therein and for detachably mounting to the vertical growth column, the hydroponic plant growth module including a lateral growth opening to allow the plant to grow laterally through toward a light emitting source, a nutrient supply system to direct aqueous crop nutrient solution through an upper opening of the hydroponic plant growth module, an airflow source to direct airflow away from the growth opening and through an under-canopy of the plant, so as to disturb the boundary layer, and a control system for regulating, at least one growing condition in an area in or adjacent to the under-canopy.

A plant growing system configured for high density crop growth and yield, including an environmentally-controlled growing chamber and a vertical growth column within, the column configured to support a hydroponic plant growth module which is configured for containing and supporting plant growth media for containing and supporting a root structure of at least one gravitropic crop plant growing therein and for detachably mounting to the vertical growth column, the hydroponic plant growth module including a lateral growth opening to allow the plant to grow laterally through toward a light emitting source, a nutrient supply system to direct aqueous crop nutrient solution through an upper opening of the hydroponic plant growth module, an airflow source to direct airflow away from the growth opening and through an under-canopy of the plant, so as to disturb the boundary layer, and a control system for regulating, at least one growing condition in an area in or adjacent to the under-canopy.

A tree rooting enclosure apparatus including a body housing with a cylindrical body base having a pair of opposing tapered ends culminating into a pair of opposing end openings. The body and end openings are structured to accommodate a portion of a plant therethrough. The body includes a plurality of exterior longitudinal channels extending the length of the cylindrical body base. The apparatus as a whole is made of two removably engaged elongate halves structured to surround a selected portion of a plant and attach to itself with a water-resistant fit around the selected portion of the plant.

A tree rooting enclosure apparatus including a body housing with a cylindrical body base having a pair of opposing tapered ends culminating into a pair of opposing end openings. The body and end openings are structured to accommodate a portion of a plant therethrough. The body includes a plurality of exterior longitudinal channels extending the length of the cylindrical body base. The apparatus as a whole is made of two removably engaged elongate halves structured to surround a selected portion of a plant and attach to itself with a water-resistant fit around the selected portion of the plant.

In various example embodiments, a bio cell system is described comprising one or more bio cell units, each comprising a primary tank and one or more secondary tanks, which tanks each comprise side walls, a floor connected to the side walls, and a removable cover. The cover of the tank comprises a lighting system comprising variable output lights and a controller connected to the lighting system comprising code for varying a time period of light output of the lights of the secondary tanks to be out of phase with a time period of light output of the lights of the primary tank.