A system, comprising: a storage workspace including a first framework defined by a series of first uprights, the first uprights supporting a grid of two substantially perpendicular sets of rails; and a plurality of containers for storing objects, wherein the plurality of containers are arranged in stacks, each stack of containers is located underneath a grid space in the workspace; and a grid extension including a continuation of the two substantially perpendicular sets of rails, and wherein the plurality of containers can be moved by one or more load handling devices between the storage workspace and an area beneath the grid extension, wherein the area beneath the grid extension is configured for positioning a roll cage such that containers can be placed or removed from the roll cage.

Provided is an environment control house 1 which can have improved strength by employing a multifaceted structure. The environment controlled greenhouse 1 comprises: a main body portion 10 and a pair of wall portions 20, wherein the main body portion 10 comprises: a top surface portion 101 formed into a rectangular shape and disposed at the topmost portion; a pair of rectangular upper skirt surface portions 102 connectedly installed to respective edges in the transverse direction of the top surface portion 101; and a pair of rectangular lower skirt surface portions 103 connectedly installed to an edge in the installation direction of the respective upper skirt surface portions 102 and disposed in a sloped manner with respect to an installation surface L, and wherein each of the wall portions 20 comprises: a center wall surface portion 210 connectedly installed to the edge in the longitudinal direction of the top surface portion 101; a pair of middle wall surface portions 220 connectedly installed to respective edges in the transverse direction of the center wall surface portion 210 and to the edge in the longitudinal direction of the upper skirt surface portion 102; and a pair of side wall surface portions 230 connectedly installed to an edge in the transverse direction of the respective middle wall surface portions 220 and to an edge in the longitudinal direction of the respective lower skirt surface portions 103.

A hydration system for an indoor gardening appliance includes sump for collecting water used to hydrate plants and a water supply containing fresh water. The sump and the water supply are fluidly coupled to a supply conduit and a pump assembly urges a flow of liquid through the supply conduit. A diverter assembly controls the amount of liquid recirculated from the sump and the flow of fresh water from the water supply. The hydration system further includes a drain valve that selectively discharges liquid from the sump to an external drain.

A hydration system for an indoor gardening appliance includes sump for collecting water used to hydrate plants and a water supply containing fresh water. The sump and the water supply are fluidly coupled to a supply conduit and a pump assembly urges a flow of liquid through the supply conduit. A diverter assembly controls the amount of liquid recirculated from the sump and the flow of fresh water from the water supply. The hydration system further includes a drain valve that selectively discharges liquid from the sump to an external drain.

A gardening appliance and method of operation during Jewish holidays is provided herein. The 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 controller may be configured for determining a Jewish holiday, such as the Sabbath, and may selectively control the indoor gardening appliance according to an operation routine for the Jewish holiday.

A growing device (mini-greenhouse) comprising a dome for growing crops therein and a light module operably installed on an exterior of the dome for projecting a light beam onto the crops. The dome comprises one or more openings/cutouts therein poisoned at locations that match the locations of corresponding lights of the light module such that the path of the light beam is unobstructed by the material of the dome. The light module is configured to dissipate the heat generated by the lights away from the dome, whereby the base portion of the light which includes the necessary circuitry is contained within the light module and the light beam projected in the dome is either reflected by a protruding reflector that penetrates the dome or a flat reflector that projects the light through the opening. The light module may include vents and/or fans for dissipating the heat into the atmosphere.

A growing device (mini-greenhouse) comprising a dome for growing crops therein and a light module operably installed on an exterior of the dome for projecting a light beam onto the crops. The dome comprises one or more openings/cutouts therein poisoned at locations that match the locations of corresponding lights of the light module such that the path of the light beam is unobstructed by the material of the dome. The light module is configured to dissipate the heat generated by the lights away from the dome, whereby the base portion of the light which includes the necessary circuitry is contained within the light module and the light beam projected in the dome is either reflected by a protruding reflector that penetrates the dome or a flat reflector that projects the light through the opening. The light module may include vents and/or fans for dissipating the heat into the atmosphere.

An exemplary robotic parking device of the present disclosure includes a number of stacks of containers. The stacks being positioned within a frame structure including uprights and a horizontal grid disposed above the stacks. The grid having substantially perpendicular rails on which load handling devices can run. Cars or vehicles are positioned in containers and are moved into and out of the stacks by the robotic handling devices running on the grid. The cars are put into the grid at entry points that may be positioned at points under the stacks.

A vehicle for use with an object handling system, the object handling system including two substantially perpendicular sets of rails forming a first grid, a plurality of first uprights supporting the first grid, a plurality of containers arranged in stacks, each stack being located underneath the first grid, one or more robotic load handling devices configured to drive on top of the rails of the first grid, the one or more load handling devices including means for removing or replacing at least one container from the stacks. The vehicle includes two substantially perpendicular sets of rails forming a second grid substantially at the top of the vehicle above a storage space for carrying containers. The second grid interfaces with the first grid to allow the one or more load handling devices to drive from the rails of the first grid onto the rails of the second grid.

A storage system is described where goods are stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked out. Each container may be provided with connectors having a push fit male connector located at a top edge of the container and a female connector at a bottom edge of the container. Adjacent containers in a stack can be linked by routing means, which form moldings on each container. The connectors can also have spring-loaded contacts. The provision of these services within individual containers rather than across the system as a whole, allows for flexibility in storage whilst reducing cost and inefficiency.