A vehicle tilting device for tilting a delivery vehicle for increasing access to items from a storage container transported on the delivery vehicle. The vehicle tilting device comprises a base structure and a tiltable platform connected to the base structure, wherein the tiltable platform comprises guiding features adapted to guide the delivery vehicle onto the tiltable platform. The tiltable platform is arranged to be connected to a delivery grid cell of a delivery rail system such that that there is a path to and/or from the tiltable platform for the delivery vehicle via the delivery grid cell. The invention is also related to an access station, a delivery system and a method of accessing a storage container.

Guidance systems and methods for a material handling vehicle are provided. A guidance system can include a sensor and a processor unit. The sensor can be configured to measure a distance to an external object within a field of view of the sensor and output distance information corresponding to the measured distance. The processor can be configured to receive the distance information from the sensor, transform the distance information from a sensor coordinate system to a material handling vehicle coordinate system, perform pattern recognition on the transformed distance information to identify an aisle feature, create an aisle model based on the identified aisle feature, and determine a guidance instruction for the material handling vehicle based on the aisle model. The aisle model can include information corresponding to the aisle feature. The guidance instruction may be configured to align the material handling vehicle within an aisle.

Autonomous modular robots and methods of use are disclosed herein. An example system includes a first assembly includes a first controller having a first processor that causes a first assembly support to translate along a first axis and align with a container placed on the first assembly support which is connected to a third assembly. The third assembly is configured to release a lid when the container has been engaged with the lid. The lid and container form a second assembly that includes a second processor and a second sensor assembly located in the lid. A transfer assembly can transfer an object into and out of the container. The first processor can determine a position and orientation of a delivery platform, planned movement and position of the second assembly, and planned operations of the transfer assembly in order to deliver a package to the delivery platform.

The invention concerns a transport vehicle and a method for the trouble-free transport of load shelves in workshops with partially autonomous operation, having the following features: (a) a vehicle body with a carrier plate for receiving and transporting a load shelf with cargo, with two separately driven drive wheels, at least one support wheel being provided at the front and at the rear of the vehicle body in each case; (b) a transverse link which connects the drive wheels which are each pivotable via an angled lever about the rotational axis, such that the drive wheels can carry out vertical movements independently of each other; (c) a centrally disposed adjusting element which, via a lifting-turning lever and a thrust rod connected thereto, can move two front lifting rods and two rear lifting rods in order to raise or lower the carrier plate; (d) a system for supplying energy to the vehicle body; and (e) at least one 3D scanner and at least one light field sensor in the front region of the vehicle body.

System includes an article supply location that includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container, and one or more removal devices that transport the container to a location of further processing. System further includes a control system configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container, deposit the article in the destination container, and transport the destination container to a location for further processing by manipulation of the removal device.

An industrial truck, configured for driverless, autonomously-acting operation for a load to be transported, includes at least a control system configured to control and to steer the industrial truck, and an evaluation unit configured to generate a signal for stopping the industrial truck. A detector device configured to recognize persons and/or objects located in a route is connected to the control system. The control system is configured to check a protective field and/or a warning field of the detector device, and the protective field and/or the warning field is automatically switchable in dependence on a position of the industrial truck and/or detected obstacles in the route of the industrial truck.

A doffing apparatus can be configured to couple to an automatically guided vehicle (AGV). The doffing apparatus can comprise at least one elongate arm, each elongate arm having a proximal end, a distal end, and a length, and at least one driver, each driver being configured to move along a respective elongate arm to move a bobbin toward the distal end of the elongate arm. The doffing apparatus can further comprise at least one alignment device. The doffing apparatus can further comprise a processor, wherein the processor is configured to: receive feedback from the at least one alignment device, provide a control signal to cause the AGV to align the elongate arm with a receptacle at a loader, and move the driver a select distance along the length of the elongate arm.

A mobile transport system includes a vehicle frame, first and second pairs of support wheels, first and second drive wheels, and a swing frame. A drive unit including a drive frame is disposed on the swing frame. The first drive wheel is rotatably supported on a first swing arm, and the second drive wheel is rotatably supported on a second swing arm. The first and second swing arms are coupled to each other by a coupling unit, such that a pivot motion of the first swing arm about a first swing axis in a first pivot direction brings about a pivot motion of the second swing arm about a second swing axis in a second pivot direction oriented opposite to the first pivot direction.

Examples provide a system for a temperature-controlled receiving tunnel. A main body includes an interior compartment and a set of adjustable bulkheads configured to create a set of temperature-controlled zones within the interior compartment. A set of cooling devices are configured to adjust an internal temperature of the set of temperature-controlled zones within the interior compartment. A control device analyzes dynamic truck delivery data and ambient temperature data to generate a predicted cooling time and a cooling initiation time. The predicted cooling time comprises an estimated quantity of time after the cooling initiation time to reach a target temperature within a selected zone in the set of temperature-controlled zones.

Industrial truck, in particular a tri-lateral sideloader, comprising

a chassis (6),
a mast (8) arranged on the chassis (6),
a cab (12),
a support structure (9) supporting the cab (12), which can be moved up and down on the mast (8) together with the cab (12) and has at least one cantilever arrangement (24; 124) projecting from the mast (8), which arrangement extends underneath the cab (12) and supports a load-carrying assembly (36) arranged in front of the cab (12),
and a device for reducing vibrations having vibration components transverse to the main direction of travel (G) of the industrial truck, which device allows vibration-reducing movements of the load-carrying assembly (36) relative to the mast (8),
characterised in that
the cantilever arrangement (24; 124) has a division, having a first cantilever portion (50a; 150a), which is coupled to the mast (8) and guided thereon in a height-adjustable manner, as a first part, and having a second cantilever portion (50b; 150b), which supports the load-carrying assembly (36) and is connected to the first cantilever portion (50a; 150a), as the other part, such that, together with the load-carrying assembly (36), it can perform vibration-reducing movements relative to said first cantilever portion, in particular having movement components transverse to the main direction of travel (G) of the industrial truck.