A rollable five-device-in-one flower container and umbrella stand comprises: a container having multiple walls and a bottom, water-regulating channels formed in the bottom, two wheel wells formed in the bottom, anti-rolling claws formed in the bottom for digging into the ground on a slope to prevent the five-device-in-one flower container and umbrella stand from sliding down the slope, an umbrella-pole receiver screwed on the bottom, U-shaped and J-shaped spring clamps hooked on the umbrella-pole receiver for creating a clamping force therebetween, two wheels partially hidden in the two wheel wells, a tubular double-wall water reservoir having spiral water-distributing tubes and spiral water-regulating foams for spirally and timely discharging the water, and spiral water-circulating slides spirally welded or molded to the walls for spirally creating multiple spiral tractions, multiple spiral layers, multiple spiral travel distances for soil and water to create multiple spiral root growths and multiple spiral nutrition absorptions.

A free-standing vertical structure is described including at least one wall structure having a plurality of live plants removably secured thereto. The wall structures may also include non-botanic media in combination with the plurality of plants such as traditional media, to form a new mixed media format for conveying information, herein referred to as botanic media. The plurality of plants may be configured to surround the non-botanic media to create a frame or border. The plants may also be arranged and configured to display information themselves. The non-botanic media and/or plants are configured on the wall structure to convey information readily perceivable by a passerby. The plants are preferably hydroponically-fed with nutrients and water from an irrigation system.

A free-standing vertical structure is described including at least one wall structure having a plurality of live plants removably secured thereto. The wall structures may also include non-botanic media in combination with the plurality of plants such as traditional media, to form a new mixed media format for conveying information, herein referred to as botanic media. The plurality of plants may be configured to surround the non-botanic media to create a frame or border. The plants may also be arranged and configured to display information themselves. The non-botanic media and/or plants are configured on the wall structure to convey information readily perceivable by a passerby. The plants are preferably hydroponically-fed with nutrients and water from an irrigation system.

Systems and methods for providing and operating a modular garden are provided. Modular gardens of the present technology may be attached to an indoor or outdoor wall. Modular gardens of the present technology include modular planters having at least one panel, a watering system, and a garden computing system that monitors plant conditions, automatically waters plants in the modular garden, and may communicate with a user personal computing device.

A garden spring for supporting climbing plants, including a hollow pipe configured in a serpentine spiral between a first end and a second end, an anchor section at the second end of the pipe, and a fluid intake at the first end of the pipe, wherein the fluid intake is in fluid communication with an interior volume of the pipe.

An apparatus for facilitating cultivation of plants. The apparatus comprises a top enclosure, a bottom enclosure, a vertical column, a cover, a tray, sensors, environmental actuators, a nutrition container, and a processing device. Further, the top enclosure houses a first component. Further, the bottom enclosure houses a second component. Further, the vertical column is interspersed between the top enclosure and the bottom enclosure is forming an interior space therebetween. Further, the cover is interspersed between the top enclosure and the bottom enclosure, encloses the interior space and allows light to enter from a surrounding of the apparatus into the interior space. Further, the tray holds a plant. Further, the sensors generate sensor data representing variables. Further, the environmental actuators control environmental variables. Further, the nutrition container contains a nutritional medium. Further, the processing device controls the environmental actuators based on the sensor data.

A pot with integrated irrigation that is provided in a single pot embodiment or in a networked embodiment having a plurality of pots wherein the present invention provides an ability to provide automated watering of plants disposed within the interior volume of the pots. The present invention includes a pot having a body wherein the body includes an upper circumferential edge. A peripheral fluid tube member is integrally formed into the upper circumferential edge and is operable to have water flow therethrough. A plurality of fluid distribution tube members are operably coupled to the peripheral fluid tube member and are oriented so as to distribute water into the interior volume of the pot. The fluid distribution tube members have fluid ejection ports and can be present in various quantities. A reservoir is provided to store water and includes a pump to move the water to the pots via tubes.

Apparatus system and method of maintaining differential atmospheric control with respect to CO2 and O2 gases in a first, stem/leaf zone, Z-1, of a plant from a second, root zone, Z-2, of the plant. The atmosphere in a stem/leaf zone is controlled to be high in CO2 while the root zone Z-2 is isolated and provided with ambient or higher O2, at a pressure to prevent infiltration of CO2 from zone Z-1. The differential atmosphere in each zone can be selectively monitored and adjusted to provide improved growing conditions. The inventive plant environment control system and method is particularly useful in the field of hydroponic and aeroponic growing enclosures, wherein nutrients are periodically provided to the roots, and a high CO2 atmosphere, plus heat and light of appropriate growth-enhancing wavelengths, are provided to the leaves for forced, high-yield growth of selected plants indoors, regardless of the season.

An irrigation apparatus and feeding system for dispersing liquid through a plant growing medium are disclosed. The apparatus includes a geometrically shaped container of variable size. Container has an outer wall with an inner surface, an open top, and a base portion configured to cover the plant growing medium. Base portion is configured with a plurality of holes for receiving liquid therethrough. Container is configured with at least one center opening therethrough having an inner wall for receiving a plant. Center opening has at least one longitudinal opening extending therefrom to outer wall to allow placement of container on plant or to allow removal of container from plant. The plurality of holes have at least one dripper for receiving liquid extending therethrough base portion such that the at least one dripper feeds plant growing medium at variable flow rates and intervals and provides stability for apparatus to be secured in plant growing medium.

An irrigation apparatus and feeding system for dispersing liquid through a plant growing medium are disclosed. The apparatus includes a geometrically shaped container of variable size. Container has an outer wall with an inner surface, an open top, and a base portion configured to cover the plant growing medium. Base portion is configured with a plurality of holes for receiving liquid therethrough. Container is configured with at least one center opening therethrough having an inner wall for receiving a plant. Center opening has at least one longitudinal opening extending therefrom to outer wall to allow placement of container on plant or to allow removal of container from plant. The plurality of holes have at least one dripper for receiving liquid extending therethrough base portion such that the at least one dripper feeds plant growing medium at variable flow rates and intervals and provides stability for apparatus to be secured in plant growing medium.