A storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

A foldable panel combination for a modular greenhouse is described. The combination includes a first side panel hingedly connected with a first roof panel at a first hinge, a second side panel hingedly connected with a second roof panel at a second hinge, and a third hinge that hingedly connects the first roof panel to the second roof panel. The combination also includes a truss brace. In the collapsed state, the first side panel, second side panel, first roof panel, and second roof panel are stacked and the truss brace is detached. In an assembled state, the first side panel, second side panel, first roof panel, second roof panel are unfolded and truss brace is attached to the first and second roof panels to form an upright stable structure. The combination can also include a roof dormer having four hingedly connected triangular sections transitionable to a stacked collapsed state.

A foldable panel combination for a modular greenhouse is described. The combination includes a first side panel hingedly connected with a first roof panel at a first hinge, a second side panel hingedly connected with a second roof panel at a second hinge, and a third hinge that hingedly connects the first roof panel to the second roof panel. The combination also includes a truss brace. In the collapsed state, the first side panel, second side panel, first roof panel, and second roof panel are stacked and the truss brace is detached. In an assembled state, the first side panel, second side panel, first roof panel, second roof panel are unfolded and truss brace is attached to the first and second roof panels to form an upright stable structure. The combination can also include a roof dormer having four hingedly connected triangular sections transitionable to a stacked collapsed state.

A foldable panel combination for a modular greenhouse is described. The combination includes a first side panel, a second side panel, a first roof panel, and a second roof panel that are hingedly connected. The combination is transitionable between a collapsed state and an open state. In the collapsed state, the four panels are in a stacked configuration. In the open state, the panels form a sidewall-to-roof-to-roof-to-sidewall structure that can be connected with other panel combinations for linear expansion. Each panel comprises a rectangular frame and a cover for enclosing art open space in the middle of the frame.

A foldable panel combination for a modular greenhouse is described. The combination includes a first side panel, a second side panel, a first roof panel, and a second roof panel that are hingedly connected. The combination is transitionable between a collapsed state and an open state. In the collapsed state, the four panels are in a stacked configuration. In the open state, the panels form a sidewall-to-roof-to-roof-to-sidewall structure that can be connected with other panel combinations for linear expansion. Each panel comprises a rectangular frame and a cover for enclosing art open space in the middle of the frame.

A horticultural plant growing assembly includes a pair of casings, each with a bottom and a side wall. Each side wall includes an upper edge configured to engage one another to define a cavity between the casings. The plant growing assembly further includes a light system, and a plurality of frame members that are connectable together to form a frame, with the light system being attachable to the frame. The plant growing assembly is configurable into a packaged configuration and an assembled configuration. In the packaged configuration, the frame members and the light system are contained within the cavity, and in the assembled configuration the frame members are connected together to form the frame with the light system attached to the frame. One of the casings includes a shelf adapted to support a plant with the light system disposed above the shelf.

A horticultural plant growing assembly includes a pair of casings, each with a bottom and a side wall. Each side wall includes an upper edge configured to engage one another to define a cavity between the casings. The plant growing assembly further includes a light system, and a plurality of frame members that are connectable together to form a frame, with the light system being attachable to the frame. The plant growing assembly is configurable into a packaged configuration and an assembled configuration. In the packaged configuration, the frame members and the light system are contained within the cavity, and in the assembled configuration the frame members are connected together to form the frame with the light system attached to the frame. One of the casings includes a shelf adapted to support a plant with the light system disposed above the shelf.

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. A lighting assembly is positioned within the grow chamber and includes a plurality of lights that are independent movable and adjustable. A controller detects an abnormal growth condition, e.g., a plant growing in a single direction, the presence and location of bare or void regions within a particular plant, growth toward a pinch point, and other growth abnormalities. The lighting assembly may be adjusted to correct the abnormal grow condition, e.g., by modifying an illumination schedule, an illumination direction, an intensity, a wavelength, or another parameter of the generated light.

The invention provides an improved system and method for a self-contained portable greenhouse, comprising a sun-light deprivation curtain system, and with a structural arrangement that integrates the fluid (liquid and air) distribution and dispensing for such plant life-support systems as water supply and irrigation, hydroponics water, nutrient and aeration, CO2 dosing, fuel (for power generation), forced-air ventilation, whereby its associated system components are miniaturized to a scale amenable for low voltage direct-current power, which are housed within the structure. The invention also provides a system architecture wherein the electrical interface infrastructure for connecting with electricity-producing resources—such as solar panels or wind turbines—is integrated into the portable greenhouse, as is the internal electrical distribution and direct-digital control for the plant life-support systems. The invention allows for multiple portable greenhouses to be interconnected along with other distribution energy resources (DER) in a DC microgrid arrangement.

The invention provides an improved system and method for a self-contained portable greenhouse, comprising a sun-light deprivation curtain system, and with a structural arrangement that integrates the fluid (liquid and air) distribution and dispensing for such plant life-support systems as water supply and irrigation, hydroponics water, nutrient and aeration, CO2 dosing, fuel (for power generation), forced-air ventilation, whereby its associated system components are miniaturized to a scale amenable for low voltage direct-current power, which are housed within the structure. The invention also provides a system architecture wherein the electrical interface infrastructure for connecting with electricity-producing resources—such as solar panels or wind turbines—is integrated into the portable greenhouse, as is the internal electrical distribution and direct-digital control for the plant life-support systems. The invention allows for multiple portable greenhouses to be interconnected along with other distribution energy resources (DER) in a DC microgrid arrangement.