An Integrated dual-use machine is for harvesting and treating fruit on trees, in order to harvest the fruit when in season and treat the fruit on the tree with phytosanitary products. The machine includes a moveable structure, intended to shelter the fruit trees. The moveable structure includes a collection unit for the fruit that has been brought down, and is supported on one or two traction vehicles. The vehicles include at least one device for projecting and orienting air currents, at least one infrared camera, at least one collection belt, at least one load container, at least one conveyor belt that connects the collection belt to a load trailer, and a traction system that actuates tractor treads.

A hydroponic apparatus comprises an enclosed housing (2). A plurality of levels is provided in the enclosed housing (2) for supporting plant containers (9) for containing seeds or plants (11) to be grown. The apparatus includes a conveyor system (16, 14, 15) for moving the plant containers (9) on each level and/or from one level to another level within the enclosed housing (2), and a control system for controlling environmental plant growing conditions in the enclosed housing (2). The plant containers (9) can be moved to different levels within the enclosed housing (2) at different stages of growth of the plants (11) in the containers (9).

A plant grow tray system comprising a plurality of trays comprising at least one upper tray and at least one bottom tray is provided. The upper tray is placed inside the bottom tray with upper tray supports between the upper tray and the bottom tray creating a space between the trays. The upper tray and the bottom tray comprise a sealing mechanism to seal the upper tray to the bottom tray. The upper tray has a corrugated profile with crest and trough portions, air holes on the corrugated surface, a drain basin, drain flange, and drain pipe. The bottom tray has an air-flow modifier, air flange, and a drain hole. The system is designed to allow air to be ducted or exhausted from the space between the upper tray and the bottom tray enabling the delivery of conditioned, fresh, or recirculated air directly to a plant.

A plant grow tray system comprising a plurality of trays comprising at least one upper tray and at least one bottom tray is provided. The upper tray is placed inside the bottom tray with upper tray supports between the upper tray and the bottom tray creating a space between the trays. The upper tray and the bottom tray comprise a sealing mechanism to seal the upper tray to the bottom tray. The upper tray has a corrugated profile with crest and trough portions, air holes on the corrugated surface, a drain basin, drain flange, and drain pipe. The bottom tray has an air-flow modifier, air flange, and a drain hole. The system is designed to allow air to be ducted or exhausted from the space between the upper tray and the bottom tray enabling the delivery of conditioned, fresh, or recirculated air directly to a plant.

Arrangement of a closed greenhouse (10) with optimised temperature control, including at least one module (10-1 to 10-n), comprising a framework and a peripheral film so as to constitute an enclosed space, comprising a front wall (16), a rear wall (18) and two side walls, left (20) and right (22) as well as a roof (24) with ridge, as well as at least one access opening with an airlock, at least one evaporating panel (26) for water diffusion, a water supply circuit (32) and at least one interior air extractor (34), characterized in that said at least one interior air extractor (34) is disposed in the immediate vicinity of the ridge of the roof (24)

Arrangement of a closed greenhouse (10) with optimised temperature control, including at least one module (10-1 to 10-n), comprising a framework and a peripheral film so as to constitute an enclosed space, comprising a front wall (16), a rear wall (18) and two side walls, left (20) and right (22) as well as a roof (24) with ridge, as well as at least one access opening with an airlock, at least one evaporating panel (26) for water diffusion, a water supply circuit (32) and at least one interior air extractor (34), characterized in that said at least one interior air extractor (34) is disposed in the immediate vicinity of the ridge of the roof (24)

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. The grow module defines a root chamber and a plurality of apertures for positioning a root end of the plant pod in the root chamber. A resonator may be positioned on each plant pod or at each of the plurality of apertures for generating a unique sound signature when a specific plant pod is inserted into a specific aperture. A detection device, such as a microphone, measures the sound waves generated by the resonator and a controller determines a location and/or a type of the plant pod based on the unique sound signature.

The invention relates to a method of impacting the fruit production of a plant or crop by applying short-duration thermal shock streams of hot air to the plant periodically to impact the flavonoid biosynthetic pathway mechanisms in a plant thereby improving its fruit. The method includes the steps of (1) passing by the plant in a row at a speed of 1-5 mph in an improved Thermal Plant Treatment (TPT) machine, (2) ejecting from the TPT machine at least one hot stream of air in the direction of the unit plant area for no more than 15 seconds per unit plant area per pass, (3) optionally measuring the thermal shock profile that the plant is subjected with thermal sensors, and (4) repeating the thermal shock profile treatment steps (1) and (2) at pre-determined regular intervals over at least a fraction of the crop year.

The invention relates to a method of impacting the fruit production of a plant or crop by applying short-duration thermal shock streams of hot air to the plant periodically to impact the flavonoid biosynthetic pathway mechanisms in a plant thereby improving its fruit. The method includes the steps of (1) passing by the plant in a row at a speed of 1-5 mph in an improved Thermal Plant Treatment (TPT) machine, (2) ejecting from the TPT machine at least one hot stream of air in the direction of the unit plant area for no more than 15 seconds per unit plant area per pass, (3) optionally measuring the thermal shock profile that the plant is subjected with thermal sensors, and (4) repeating the thermal shock profile treatment steps (1) and (2) at pre-determined regular intervals over at least a fraction of the crop year.

The prevent invention discloses a defrosting machine column fixed support with an inclined flat leg, including a defrosting machine (1), a connecting support (2), a pedestal bolt (3), and a pedestal (4). The connecting support (2) includes an anti-tilting guide barrel (21), a fixed pillar (22), a rib plate (23), and a connecting plate (24). The pedestal (4) includes a pedestal plate (41) and a flat leg (42). The pedestal bolt (3) is used for fixedly connecting the connecting support (2) with the pedestal (4). The pedestal plates are hit into the soil so as to solve digging difficulties and low efficiency of a small diameter mounting deep hole with high accuracy requirements; each pedestal plate is respectively vertically provided with two intersecting flat legs in an inclined mode, thus balancing forces in each direction and stabilizing the defrosting machine column. The holes on the pedestal plates can integrate the soils on the inner side and outer side and two sides into one body, thus stabilizing the defrosting machine. In addition, the connecting support is employed, and standard tubes replace conventional non-standard tubes, thus saving on material cost, and transport and storage are also convenient. The support is simple in structure, convenient to implement, can be applied on pebbled land, not only reduces labour intensity when mounting, but also improves the anti-sinking, anti-horizontal torsion and anti-tilting abilities of the defrosting machine column, improves defrosting machine work reliability, and improves mounting efficiency and economic benefits of the defrosting machine.