A an energy storage system includes a crane and a plurality of blocks, where the crane is operable to move blocks from a lower elevation to a higher elevation (via stacking of the blocks) to store electrical energy as potential energy of the blocks, and then operable to move blocks from a higher elevation to a lower elevation (via unstacking of the blocks) to generate electricity based on the kinetic energy of the block when lowered (e.g., by gravity). The energy storage system can, for example, store electricity generated from solar power as potential energy in the stacked blocks during daytime hours when solar power is available, and can convert the potential energy in the stacked blocks into electricity during nighttime hours when solar energy is not available, and deliver the converted electricity to the power grid.

A an energy storage system includes a crane and a plurality of blocks, where the crane is operable to move blocks from a lower elevation to a higher elevation (via stacking of the blocks) to store electrical energy as potential energy of the blocks, and then operable to move blocks from a higher elevation to a lower elevation (via unstacking of the blocks) to generate electricity based on the kinetic energy of the block when lowered (e.g., by gravity). The energy storage system can, for example, store electricity generated from solar power as potential energy in the stacked blocks during daytime hours when solar power is available, and can convert the potential energy in the stacked blocks into electricity during nighttime hours when solar energy is not available, and deliver the converted electricity to the power grid.

A an energy storage system includes a crane and a plurality of blocks, where the crane is operable to move blocks from a lower elevation to a higher elevation (via stacking of the blocks) to store electrical energy as potential energy of the blocks, and then operable to move blocks from a higher elevation to a lower elevation (via unstacking of the blocks) to generate electricity based on the kinetic energy of the block when lowered (e.g., by gravity). The energy storage system can, for example, store electricity generated from solar power as potential energy in the stacked blocks during daytime hours when solar power is available, and can convert the potential energy in the stacked blocks into electricity during nighttime hours when solar energy is not available, and deliver the converted electricity to the power grid.

A system includes a crane and an exchangeable tool. The crane and the tool respectively, include an upper tool connector with tool retainers and a lower tool connector which can be interconnected, e.g. a male and female connector, e.g. the lower tool connector of the tool being embodied as a shank provided with a shoulder and the upper tool connector as a tool clamp with a female, open-centered body. A tool suspension device includes the upper tool connector and a travelling block member. The tool clamp has multiple mobile tool retainers adapted toin a non-operative positionallow introduction of the shank of the tool from below into the shank receiving passage andin an operative positionengage below the shoulder of the shank that has been introduced into the passage so as to suspend the tool. The upper tool connector may include a bearing allowing for swivelling of the open-centered body, and e.g. a rotational drive operative between the clamp housing and the female, open-centered body to actively drive said swivelling.

A system includes a crane and an exchangeable tool. The crane and the tool respectively, include an upper tool connector with tool retainers and a lower tool connector which can be interconnected, e.g. a male and female connector, e.g. the lower tool connector of the tool being embodied as a shank provided with a shoulder and the upper tool connector as a tool clamp with a female, open-centered body. A tool suspension device includes the upper tool connector and a travelling block member. The tool clamp has multiple mobile tool retainers adapted toin a non-operative positionallow introduction of the shank of the tool from below into the shank receiving passage andin an operative positionengage below the shoulder of the shank that has been introduced into the passage so as to suspend the tool. The upper tool connector may include a bearing allowing for swivelling of the open-centered body, and e.g. a rotational drive operative between the clamp housing and the female, open-centered body to actively drive said swivelling.

An automated storage and retrieval system includes a track system including a first set of tracks arranged in a horizontal plane and extending in a first direction, and a second set of tracks arranged in the horizontal plane and extending in a second direction that is orthogonal to the first direction. The first set of tracks and the second set of tracks form a grid pattern in the horizontal plane including a plurality of adjacent grid cells. Each grid cell includes an opening defined by the first set of tracks and the second set of tracks such that the track system includes a plurality of openings. A plurality of storage containers are arranged in columns beneath the track system such that the storage containers are located vertically below the openings. A plurality of container handling vehicles for lifting and moving the storage containers are configured to move on the track system and access the storage containers via the openings. Each container handling vehicle of the container handling vehicles includes a lower part in contact with the track system and an upper part. The lower part has a width and a length that form a vehicle footprint. The vehicle footprint of the lower part has dimensions smaller than the opening such that a contact area of the container handling vehicle does not extend into an adjacent grid cell. The upper part, which is disposed vertically above the lower part, includes a protruding section and a recessed section. The protruding section is configured to extend beyond the lower part into the adjacent grid cell. The recessed section is of a complimentary shape to the protruding section such that the recessed section is configured to receive other protruding sections of other vehicles of the container handling vehicles. The lower part further includes a storage space configured to accommodate a storage container of the storage containers.

An automated storage and retrieval system includes a track system including a first set of tracks arranged in a horizontal plane and extending in a first direction, and a second set of tracks arranged in the horizontal plane and extending in a second direction that is orthogonal to the first direction. The first set of tracks and the second set of tracks form a grid pattern in the horizontal plane including a plurality of adjacent grid cells. Each grid cell includes an opening defined by the first set of tracks and the second set of tracks such that the track system includes a plurality of openings. A plurality of storage containers are arranged in columns beneath the track system such that the storage containers are located vertically below the openings. A plurality of container handling vehicles for lifting and moving the storage containers are configured to move on the track system and access the storage containers via the openings. Each container handling vehicle of the container handling vehicles includes a lower part in contact with the track system and an upper part. The lower part has a width and a length that form a vehicle footprint. The vehicle footprint of the lower part has dimensions smaller than the opening such that a contact area of the container handling vehicle does not extend into an adjacent grid cell. The upper part, which is disposed vertically above the lower part, includes a protruding section and a recessed section. The protruding section is configured to extend beyond the lower part into the adjacent grid cell. The recessed section is of a complimentary shape to the protruding section such that the recessed section is configured to receive other protruding sections of other vehicles of the container handling vehicles. The lower part further includes a storage space configured to accommodate a storage container of the storage containers.

The invention relates to a mobile construction crane comprising a superstructure and an undercarriage, wherein one or more electrical consumers are provided in or at the superstructure, wherein a supply of the one or more electrical consumers with electrical energy takes place by at least one current generator installed in the undercarriage.

A self-maintaining crane system including a bridge, a trolley, a hoist, and sensors for use within a hostile environment, such as a wastewater treatment facility, is presented. The bridge is movable along a pair of runway rails. The trolley is movable between the runway rails. The hoist with extendable-retractable cable is movable with the trolley. Bridge sensors determine whether the bridge has engaged home and end positions. Trolley sensors determine whether the trolley has engaged home and end positions. The bridge and the trolley are movable between home and end positions. Hoist sensors determine whether the cable has engaged a hoist home position and a hoist end position. The cable is extendable away from the home position and retractable toward the end position. Sensors facilitate automated movement of bridge, trolley, and cable so as to minimize functional impairment of the crane system by the hostile environment.

A self-maintaining crane system including a bridge, a trolley, a hoist, and sensors for use within a hostile environment, such as a wastewater treatment facility, is presented. The bridge is movable along a pair of runway rails. The trolley is movable between the runway rails. The hoist with extendable-retractable cable is movable with the trolley. Bridge sensors determine whether the bridge has engaged home and end positions. Trolley sensors determine whether the trolley has engaged home and end positions. The bridge and the trolley are movable between home and end positions. Hoist sensors determine whether the cable has engaged a hoist home position and a hoist end position. The cable is extendable away from the home position and retractable toward the end position. Sensors facilitate automated movement of bridge, trolley, and cable so as to minimize functional impairment of the crane system by the hostile environment.