A drive belt assembly for a load handling device includes a drive belt; a drive wheel; and one or more driven wheels. A first tensioning arm, having a fixed end above an elbow and a rotatable distal end pivotally attached at the elbow, is horizontally displaceable relative to the drive wheel and driven wheels. A second tensioning arm is provided wherein the drive belt is routed around the first and second tensioning arms, and the first and second tensioning arms are arranged to put pressure on the drive belt to tension the drive belt.

A traveling vehicle system includes: a plurality of traveling vehicles; and a controller that is capable of communicating with the plurality of traveling vehicles and that controls the plurality of traveling vehicles, a traveling region of the traveling vehicles having designated therein a plurality of blocking sections each of which undergoes, when occupied by one of the plurality of traveling vehicles, exclusive control to prohibit another traveling vehicle from moving thereinto. The controller determines, where in a series of operations to be executed by the traveling vehicle, the operation of the traveling vehicle from the start of traveling to stopping before executing a predetermined operation included in the series of operations is demarcated, whether or not to grant the traveling vehicle an occupation permission for the blocking sections to be occupied for the traveling vehicle to execute operations.

A traveling vehicle system includes a plurality of traveling vehicles, a controller that controls the plurality of transport vehicles, a traveling region of the traveling vehicles having a plurality of blocking sections each of which undergoes exclusive control to prohibit another traveling vehicle from moving thereinto. The traveling vehicle makes a request to the controller for occupation permissions regarding a plurality of blocking sections to be occupied by the traveling vehicle and are designated by instructions. The controller then determines, among the plurality of blocking sections for which the traveling vehicle makes a request for occupation permissions, one or more of the blocking sections that are able to allow permissions consecutively from an end thereof to be primarily occupied, based on the traveling direction of the traveling vehicle, and the controller grants the traveling vehicle the permissions for one or more blocking sections determined to allow the permissions.

A container handling vehicle for lifting a storage container from an underlying framework structure includes a container lifting assembly for lifting the storage container and a vehicle body. The container lifting assembly includes a lifting frame for releasable connection to a storage container, a lifting shaft assembly, and a plurality of lifting bands. The lifting bands are connected to the lifting frame and the lifting shaft assembly such that the lifting frame may be raised or lowered by operating the lifting shaft assembly. The vehicle body includes a sidewall and a cantilevered section from which the lifting frame depends. The cantilevered section extends laterally from an upper end of the sidewall. The container lifting assembly features a lifting frame guide assembly comprising a first guide device and a cooperating second guide device. The first guide device is provided on the lifting frame. The second guide device is slidably connected to the sidewall via at least one vertically extending rail, such that the second guide device can move in a vertical direction relative to the sidewall. The first guide device and the second guide device are arranged to interact with each other when the lifting frame is adjacent the sidewall, such that horizontal movement of the lifting frame relative to the vehicle body is restricted.

A two-dimensional rail system includes a first set of parallel rails arranged to guide movement of container handling vehicles in a first direction across the top of the frame structure, and a second set of parallel rails arranged perpendicular to the first set of rails to guide movement of the container handling vehicles in a second direction, which is perpendicular to the first direction. The first and second sets of parallel rails divide the rail system into a plurality of grid cells. A container handling vehicle for operation on the two-dimensional rail system includes: a wheel base unit, a body unit, a support section, a cantilever section, and a lifting device. The wheel base unit includes first and second sets of wheels for guiding the container handling vehicle along the rail system in the first and second directions respectively. The first and second sets of wheels form outer peripheries of the wheel base unit. The body unit includes a lower section, which is provided on the wheel base unit. The lower section has a footprint with a horizontal extent which is equal to or less than the wheel base unit. The lower section has an upper surface. The upper surface provides a first container carrying position for carrying a storage container. The support section extends vertically from the lower section. The support section has a footprint with a horizontal extent which is smaller than the footprint of the lower section. The cantilever section extends horizontally from the support section beyond the footprint of the lower section. The lifting device includes a lifting frame that is suspended from the cantilever section.

A two-dimensional rail system includes a first set of parallel rails arranged to guide movement of container handling vehicles in a first direction across the top of the frame structure, and a second set of parallel rails arranged perpendicular to the first set of rails to guide movement of the container handling vehicles in a second direction which is perpendicular to the first direction. The first and second sets of parallel rails dividing the rail system into a plurality of grid cells. A container handling vehicle for operation on the rail system includes a wheel base unit including sets of wheels for guiding the container handling vehicle along the rail system in the first and second directions; a body unit; and a lifting device. The body unit includes: a lower section which is provided on the wheel base unit; a support section extending vertically from the lower section; and a cantilever section extending horizontally from the support section. The lower section has a footprint with a horizontal extent which is equal to or less than the horizontal extent of one of the grid cells and a top surface which is at a first height. The support section has a footprint with a horizontal extent which is smaller than the footprint of the lower section. The cantilever section extends beyond the footprint of the lower section. The lifting device includes a lifting frame that is suspended from the cantilever section of the body unit. The lifting frame has a lowermost part at a second height when the lifting frame is docked in an upper position adjacent the cantilever section. The second height of the lowermost part of the lifting frame, when the lifting frame is docked in its upper position, is above the first height of the top surface of the lower section of the body unit.

A system for condition-based maintenance of an automated storage and retrieval system includes a framework structure with a rail system forming a three-dimensional storage grid structure for storing storage containers for storing items. The grid structure forms vertical storage columns each having a horizontal area defined by the size of an access opening between rails of the rail system that are arranged on the framework structure. The rail system provides available routes for container handling vehicles handling and transferring the storage containers to and from the storage columns. At least one container handling vehicle which has a container handling platform with a set of grippers for handling the storage containers. The grid structure includes one or more ports for extracting containers from the storage grid so that the storage containers can be picked and a service station for performing maintenance on the components of the storage and retrieval system. The system further includes a plurality of sensors configured to be attached to components of the storage and retrieval system for providing condition-based information linked to parts and components of the storage and retrieval system, a service regime manager configured to retrieve condition-based information from the plurality of sensors and create a service regime based on the condition-based information linked to parts and components of the storage and retrieval system and send the service regime to a local service station where condition-based maintenance is performed, and a central computer system. The central computer system is configured to: receive the condition-based information from the plurality of sensors and decide what information is to be sent to a global computer system that is part of the system for condition-based maintenance, and further sending only the information that can be of interest to other storage and retrieval systems. The global computer system is configured to receive the condition-based information from the central computer system and determine trends regarding component servicing or changing of components and further the global computer system transfers the information on the trend to the individual central computer system's service regime manager.

A storage tower for storing storage containers includes a plurality of horizontally extending container supporting frameworks distributed with vertical offsets. The plurality of horizontal container supporting frameworks includes a first container supporting framework and at least one second container supporting framework arranged beneath and extending parallel to the first container supporting framework. Each of the first and the at least one second container supporting frameworks includes a horizontally extending container support with principal directions in a first direction and an orthogonal second direction. Each container support is configured as a matrix of container spaces with a plurality of columns of container spaces arranged in the first direction and a plurality of rows of container spaces arranged in the second direction. Each row of container spaces of the first container supporting framework is configured to receive a plurality of storage containers and displays at least one opening extending along the second direction, the at least one opening having an opening size being at least a maximum horizontal cross section of the storage containers to be stored. The at least one opening of the first container supporting framework and the at least one opening of the at least one second container supporting framework can be aligned vertically with respect to each other. At least one container support is displaceable along the second direction. At least one container supporting framework further includes a support displacement device configured to displace the displaceable container support.

A storage system including a storage grid including vertical column profiles defining a plurality of grid columns. The grid columns include storage columns, in which storage containers can be stored one on top of another in vertical stacks. The storage grid including at least one rail grid at the upper ends of the column profiles, and a first container handling vehicle and a second container handling vehicle. The first and the second container handling vehicles each include at least one wheel base unit and a first container handling module or a second container handling module. Each wheel base unit having a wheel arrangement for movement of the wheel base unit in two perpendicular directions upon a rail grid of the storage system. The first container handling module is a different type of container handling module to the second container handling module.

A delivery vehicle operates on a two-dimensional rail system with rails extending in a first direction and a second direction. The second direction is perpendicular to the first direction. The delivery vehicle includes a vehicle body; two sets of wheels connected to the vehicle body for engagement with the underlying rail system and for moving the delivery vehicle in the first and second directions; a container carrier for supporting a container from below, wherein the container carrier comprises a first conveyor; a conveyor drive shaft for driving the first conveyor; and at least one drive coupling. The at least one drive coupling includes a connection interface accessible from an outer side portion of the vehicle body. The drive coupling is rotatably connected to a motor drive shaft such that when the motor drive shaft is rotated the drive coupling and the connection interface are rotated.