A carrier vehicle can be used for a plurality of purposes. A carrier vehicle (100) according to the disclosure includes a flat plate (120) and a moving section (130). A through-hole (122p) is provided in the flat plate (120). The moving section (130) causes the flat plate (120) to move. The moving section (120) is switched among a reference mode in which the flat plate (120) is caused to move to a reference position, a penetrating mode in which the through-hole (122p) of the flat plate (120) is penetrated through, and a moving mode in which the flat plate (120) is caused to move from the reference position to a moving position without penetrating through the through-hole (122p) of the flat plate (120).

A carrier vehicle can be used for a plurality of purposes. A carrier vehicle (100) according to the disclosure includes a flat plate (120) and a moving section (130). A through-hole (122p) is provided in the flat plate (120). The moving section (130) causes the flat plate (120) to move. The moving section (120) is switched among a reference mode in which the flat plate (120) is caused to move to a reference position, a penetrating mode in which the through-hole (122p) of the flat plate (120) is penetrated through, and a moving mode in which the flat plate (120) is caused to move from the reference position to a moving position without penetrating through the through-hole (122p) of the flat plate (120).

A mobile fitness plaza configured to be coupled to or integrated into a vehicle to provide mobile fitness stations to one or more users. The mobile fitness plaza includes one or more alcove compartments providing a storage space for exercise equipment and one or more awnings configured to be selectively adjusted between a stowed position and a deployed position to provide shelter and protection for equipment stowed therein and users positioned beneath the one or more awnings.

A mobile fitness plaza configured to be coupled to or integrated into a vehicle to provide mobile fitness stations to one or more users. The mobile fitness plaza includes one or more alcove compartments providing a storage space for exercise equipment and one or more awnings configured to be selectively adjusted between a stowed position and a deployed position to provide shelter and protection for equipment stowed therein and users positioned beneath the one or more awnings.

A pallet structure includes a positioning mechanism is provided. The positioning mechanism includes an engaging element disposed on a sloping edge and adapted to be engaged with slits formed on the inclined surface of a vehicle. A coil spring is connected between the engaging element and the sloping edge and biasing the engaging element to protrude outward from an outer surface of the sloping edge. A retaining element is disposed between an inner surface of the sloping edge and a bottom deck board of the pallet and configured to retain the engaging element to move between an engaging position and a disengaging position. The protruding end of the engaging element is protruded outward from the outer surface of the sloping edge in the engaging position, and the protruding end of the engaging element is not protruded from the outer surface of the sloping edge in the disengaging position.

A product conveyance robot includes: a travel portion configured to travel on a road surface; a holding portion provided above the travel portion and configured to hold a product, the holding portion being provided rotatably around a lateral turn axis extending in the height direction of the holding portion; and a controller configured to control driving of the travel portion and a rotation angle of the holding portion around the lateral turn axis.

A self-propelled slag transporter, The self-propelled slag transporter includes a drive, a chassis, a lifting device with at least one lifting drive and a receiving device for receiving a metallurgical transport container, in particular a slag container, wherein the receiving device is designed to be height-adjustable by the lifting device, and wherein the chassis has at least two crawler tracks.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base have omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base, one or more modular containers, and the lid may be electrically linked to provide information to be used in a number of ways. For example, the electrical link may allow two or more modular robots to communicate with each other, enable external displays of multiple modules to act as one large unit, control the motion of the drawers, e.g., allowing them to open/close, and allow the processor(s) in the lid to communicate with the drive system of the omni-directional wheels. A set of alternating interlocking rails and tracks on corresponding surfaces enable the various layers of the modular robot to interlock with one another. Interlocking of multiple modular containers may be established by sliding one surface over the other. These sections may be used to create modular robots of varying sizes.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base have omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base, one or more modular containers, and the lid may be electrically linked to provide information to be used in a number of ways. For example, the electrical link may allow two or more modular robots to communicate with each other, enable external displays of multiple modules to act as one large unit, control the motion of the drawers, e.g., allowing them to open/close, and allow the processor(s) in the lid to communicate with the drive system of the omni-directional wheels. A set of alternating interlocking rails and tracks on corresponding surfaces enable the various layers of the modular robot to interlock with one another. Interlocking of multiple modular containers may be established by sliding one surface over the other. These sections may be used to create modular robots of varying sizes.

A pivoting system has an electronic device pivotably mounted on a cargo platform. A base is coupled to a cargo support. A linkage rod slidably engages with the cargo platform. A proximal pivot pivotably couples the proximal end of the linkage rod arm to the base. A device pivot pivotably couples the electronic device to the cargo platform. A distal pivot pivotably couples the distal end of the linkage rod to the electronic device. The pivoting system causes pivoting of the electronic device between a lower general horizontal position and an upper general horizontal position.