Waterproof and UV (ultraviolet) radiation blocking protective cover (1) for hanging fruit, CHARACTERIZED by a sheet (10) made of an expanded polyethylene material that blocks ultraviolet radiation (EPE-UV), whose shape is a flat geometric figure, with a main straight cut (11) running from the midpoint to the edge of the sheet and an arrangement of cuts and grooves that make up the attachment system when the cover is fitted on the fruit.

An electronic cigarette, including: a cigarette holder assembly; a fixing seat assembly; an atomization assembly; a gas flow control assembly; and a glass housing. The cigarette holder assembly is made of metal. The fixing seat assembly operates to fix the glass housing and to regulate an air flow. The atomization assembly is disposed inside the glass housing. The heating wires are disposed inside the atomization assembly. The cigarette holder assembly is connected to the fixing seat assembly in the manner of plugging. The glass housing is connected to a middle support via a fixing jaw. The atomization assembly is assembled with the gas flow control assembly using screw threads to form an integrated structure, and the integrated structure of the atomization assembly and the gas flow control assembly is then assembled with the fixing seat assembly.

A method includes receiving, using at least one processor, first sensor data pertaining to plant-related parameters of each of multiple first plants over time. The method also includes storing the first sensor data in at least one memory. The method further includes identifying, using the at least one processor, an issue affecting at least one of the first plants. The method also includes analyzing, using the at least one processor, at least some of the stored first sensor data to generate a predictive model associated with the issue. The method further includes receiving, using the at least one processor, second sensor data pertaining to plant-related parameters of each of multiple second plants. In addition, the method includes identifying, using the at least one processor, at least one of the second plants to receive one or more interventions by applying the predictive model to the second sensor data.

A method includes receiving, using at least one processor, first sensor data pertaining to plant-related parameters of each of multiple first plants over time. The method also includes storing the first sensor data in at least one memory. The method further includes identifying, using the at least one processor, an issue affecting at least one of the first plants. The method also includes analyzing, using the at least one processor, at least some of the stored first sensor data to generate a predictive model associated with the issue. The method further includes receiving, using the at least one processor, second sensor data pertaining to plant-related parameters of each of multiple second plants. In addition, the method includes identifying, using the at least one processor, at least one of the second plants to receive one or more interventions by applying the predictive model to the second sensor data.

The present invention relates to an apparatus and method for the generation of directed vapor from a liquid source. Vaporization takes place within a device capable of confining boiling to a geometrically small volume, and expelling it as heated vapor via capillary vaporization. The foregoing is accomplished through the use of a lightweight, compact and portable personal vaporization device that generates heated vapor by the flash boiling of small volumes of aqueous liquid in a safe and energy-efficient manner. Further, the production of vapor absent microbes in aqueous systems is accomplished through the combination of microporous componentry and flash vaporization. The apparatus and methods are directed toward personal humidification for comfort and therapeutic purposes in the case of aqueous liquids, but may also be used with other, non-aqueous liquids.

A rover includes a base having wheels and a propulsion system coupled to the wheels to propel the rover around a field. A tower is coupled to the base and extends over the base. Sensors are set on the tower and the base and are configured to sense environmental conditions around the rover at different elevations. A computing system includes a processor and memory. The memory is configured to receive measured data from the sensors and determine an amount and manner of water to be dispensed on plant life in the field.

A heated spray system for frost protection and prevention is described. Heated water, such as groundwater, is delivered through a spray system to the area surrounding the irrigated crops, thus increasing the temperature near the crops and preventing frost damage. Surface water is provided, by a drip irrigation line. The crops are protected from excessive irrigation with the addition of protective covers, a protective curtain, and a drainage system. When spraying groundwater for temperature control, the covers, curtain, and drainage system prevent the water from reaching the roots of the crops, and thus prevent the groundwater from damaging the roots due to contaminants and pollutants in the groundwater.

A device is described for preventing damage to crops by means of heated ambient air, the device comprising gas reservoirs a gas burner, a centrifugal fan and a heating device. The heating device branches off a part of the flow of the heated ambient air to an outlet of the centrifugal fan and allows it to flow to the bottom side of the at least one gas reservoir.

A device is described for preventing damage to crops by means of heated ambient air, the device comprising gas reservoirs a gas burner, a centrifugal fan and a heating device. The heating device branches off a part of the flow of the heated ambient air to an outlet of the centrifugal fan and allows it to flow to the bottom side of the at least one gas reservoir.

A modular lighting system having a plurality of lighting units is disclosed. Each lighting unit includes a plurality of LEDs coupled to a microcontroller that is coupled to a first cable connector and a second cable connector. The system further includes a control box having a user interface, the control box communicatively coupled to each lighting unit through a plurality of cables, the plurality of lighting units and the control box all communicatively and releasably coupled to each other in series. The control box is configured to send through the first cable connector an address packet. For each lighting unit, the microcontroller is configured to adopt a first address received as a first address packet while in an addressable state, the first address being unique among the lighting units, and further configured to send a second address packet to another microcontroller after placing it in the addressable state.