A system (100) for producing a plant (35), the system having an indoor environment, a plurality of plant holders (1) for growing and transporting a plant therein, a controller (105) for at least controlling temperature and humidity in the indoor environment. The plant holder has a semi-permeable foil (20) defining a non-planar boundary of an interior space and an exterior space, a reservoir (2), having an amount of liquid for feeding the plant. The reservoir (2) and the semi-permeable foil (20) are arranged to allow the plant to grow in the interior space. The semi-permeable foil (20) has permeation of water vapor.

A system (100) for producing a plant (35), the system having an indoor environment, a plurality of plant holders (1) for growing and transporting a plant therein, a controller (105) for at least controlling temperature and humidity in the indoor environment. The plant holder has a semi-permeable foil (20) defining a non-planar boundary of an interior space and an exterior space, a reservoir (2), having an amount of liquid for feeding the plant. The reservoir (2) and the semi-permeable foil (20) are arranged to allow the plant to grow in the interior space. The semi-permeable foil (20) has permeation of water vapor.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber and defining a root chamber. A hydration system is fluidly coupled to the root chamber for selectively implementing a hydration cycle where the root chamber is charged with mist and an air circulation system selectively urges a flow of air through the root chamber to maintain a desired temperature. A controller is configured for stopping the flow of air during the hydration cycle, e.g., to minimize disruption of the hydration cycle. The stopping of the flow of air may be time-based, e.g., based on the start/end times of the hydration cycle, or may be based on moisture level, e.g., as measured by an optical sensor.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber for receiving a plurality of plant pods. A moisture management system includes an evaporator plenum in fluid communication with the grow chamber and a fan assembly that recirculates air from the respective grow chambers and/or the ambient environment through an evaporator positioned within the evaporator plenum. In this manner, chamber humidity may be regulated while water is extracted from the air which may be used by a hydration system to hydrate plants.

The present invention discloses a hydroponic field irrigation system comprising a field module for growing turfgrass. The field module comprises an energy absorbing mechanism comprising a horizontal spring layer and a growth medium comprising a steel grid layer, wherein the horizontal spring layer absorbs vertical forces exerted by external loads, and the steel grid layer is positioned on top of the horizontal spring layer for holding a plurality of turf sods. The hydroponic field irrigation system further comprises a used water tank for receiving water from the field module, an ultra-violet (UV) unit for disinfecting the water received from the used water tank, a water quality management unit for adjusting quality of the water received from the ultra-violet (UV) unit, a geothermal unit for conditioning temperature of water received from the water quality management unit and plurality of solenoid valves for pumping water into and out of the field module.

A horticultural container includes a tag slot for receiving a display tag. The tag slot has an inner wall and an outer wall spaced widthwise from one another, and one of the inner or outer walls has at least two curved peaks separated by a valley and extending into the slot towards the other of the inner or outer wall to hold the tag against the other of the inner or outer wall. The peaks provide a radius that reduces cracking of the tag and increases longevity thereof, and reduces tag sagging, collapsing, or curling.

Methods and systems are disclosed configured to control the planting, application of pesticides, and harvesting of greenhouse crops, such as herbs. The greenhouse may include a variety of sensors, such as moisture sensors, ph sensors, and/or CO2 sensors. Unmanned vehicles may be utilized to capture crop images, and a learning engine may be used to determine the size of greenhouse crops. Such sensor data may be used to predict crop availability. A predication engine may be utilized to predict demand for greenhouse crops using current and historical orders for greenhouse crops. Greenhouse crop production instructions may be generated and transmitted to a greenhouse computer system to cause crops to be sown or harvested. Pallet loading instructions may be generated regarding the loading of specified quantities of crop packs on respective pallets for shipment to a destination.

Embodiments of the invention as described herein relate to a series of linked rotatable turntables that can be powered by various means. The turntables are mounted onto a frame that can be configured into a plurality of different shapes and sizes. The turntables can be configured in numerous different heights and sizes and they can be driven in either a clockwise or counterclockwise direction. The device can be driven via various different mechanisms including, but not limited to, chain, belt hydraulic and pneumatic. The device may be powered by, for example, mains, battery or solar.

A plant training device includes a first portion including a first portion base and a plurality of angularly spaced-apart first indexing elements extending along an exterior of the first portion base. A second portion includes a second portion base having a first end and a second end opposite the first end. The second portion base defines an interior cavity structured to receive at least a portion of the first portion base therein, the interior cavity including a plurality of angularly spaced-apart recesses. Each recess is structured to complementarily slidingly engage and receive therein a first indexing element of the first portion whenever at least a portion of the first portion base is received in the second portion interior cavity at the second portion base first end, to rotationally secure the first portion and the second portion with respect to each other.

A tessellated ceramic apparatus for plant growth is set forth devised to support germination and plant growth upon an exterior surface. Water moves under osmotic pressure from a water storage volume disposed in osmotic communication with the ceramic, through the ceramic to become available water at the exterior surface. A graduated cross-section regulates water flow from a water storage volume through to the exterior surface along a pressure gradient exerted by the water head. Plant growth is facilitated within a plurality of tessellated indentations disposed upon the exterior surface and growth may be restricted from areas of the exterior surface by application of gloss, glaze, sealants and/or other surface features that may blend design elements to augment and support a living design.