Disclosed is a child carrier seat arrangement comprising: a child seat configured to receive a child; a carrier base detachably attached to the child seat; a wheel arrangement coupled to the carrier base, wherein the wheel arrangement provides movement to the child carrier seat arrangement; a processor coupled to the carrier base, wherein the processor is configured to: receive a first input to make the child carrier seat arrangement work in a luggage mode, wherein, in the luggage mode, a user is configured to carry the child carrier seat arrangement as hand luggage; receive a second input to make the child carrier seat arrangement work in a manual mode, wherein, in the manual mode, a user is configured to navigate the child carrier seat arrangement; receive a third input to make the child carrier seat arrangement work in an automatic mode; and a sensor module coupled to the processor, wherein the sensor module is configured to provide instructions to the processor in the automatic mode for autonomous navigation of the child carrier seat arrangement.

The present disclosure provides a conveyance system and the like capable of preferably conveying a conveyed object in accordance with a state of the conveyed object. The conveyance system includes a conveyance robot, a drive controller, which is a controller, an image data acquisition unit, and a setting unit. The conveyance robot conveys the conveyed object. The drive controller controls an operation of the conveyance robot. The image data acquisition unit acquires image data obtained by capturing images of the conveyed object. The setting unit sets an operation parameter of the conveyance robot in the drive controller based on the acquired image data.

A conveyance system and the like capable of preferably conveying a conveyed object is provided. The conveyance system includes a conveyance robot, which is a conveyance apparatus, a drive controller, which is a controller, an information accepting unit, and a setting unit. The conveyance robot conveys the conveyed object. The drive controller controls an operation of the conveyance robot. The information accepting unit accepts an input from a user regarding information indicating stability of the conveyed object in a conveyance state. The setting unit sets an operation parameter of the conveyance apparatus in the drive controller based on the accepted information.

The invention relates to a pram comfort device (10, 12) for a pram, in particular a pram axle and/or a pram wheel (12), with an axle and/or a wheel (200), wherein the axle is designed as what is referred to as an intelligent axle and/or the wheel (200) is designed as what is referred to as an intelligent wheel (200), and an additional comfort function can be provided for the pram by means of the axle and/or by means of the wheel (200). Furthermore, the invention relates to a pram underframe or a pram, wherein the pram underframe or the pram has a pram comfort device (10, 12) according to the invention.

Some embodiments include apparatuses providing control over movement of motorized transport units at a retail facility, comprising: multiple self-propelled motorized transport units; a wireless communication network; and a central computer system, wherein the central computer system comprises: a transceiver; a control circuit; and a memory storing computer instructions that when executed cause the control circuit to: receive an override command, from a worker associated with the retail facility, to cause a first motorized transport unit of the multiple motorized transport units to implement one or more actions; confirm a valid authorization of the worker to override one or more operating limits of the first motorized transport unit; and override the one or more operating limits and communicate one or more instructions to the first motorized transport unit configured to cause the first motorized transport unit to implement the one or more actions in accordance with the override command.

A kit for motorizing a golf bag cart, a motorized golf bag cart, and a method of motorizing a golf bag cart are disclosed herein. The kit can include brackets having clamps, a golf cart drive unit, and a remote control. Each bracket is used to replace a rear wheel assembly of a non-motorized golf bag cart. The clamps are used to attach the golf drive unit to the cart. The remote control is used to control and steer the cart via the attached golf cart drive unit. The golf cart drive unit includes two motors, two axles, two wheels and an axle aligning member. The axles slide relative to the axle aligning member to accommodate golf bag carts having different rear wheel spacing.

A track system for a cart includes a plurality of curved modular track sections for the cart. Each of the plurality of curved modular track sections includes one or more rails configured to engage with the cart on the track, and one or more reservoir sections configured to receive liquid from the cart. Each of the plurality of curved modular track is tilted relative to ground by a predetermined angle such that the one or more reservoir sections are configured to direct the liquid to a predetermined area. Each of the plurality of curved modular track sections includes a gear system configured to engage with a gear of the cart.

The smart shopping cart is a cart for storing and transporting groceries or other articles, having a hanger pole rising from the basket for hanging bags and the like. The smart shopping cart includes a basket and a plurality of wheels secured to a lower surface of a lower wall of the basket. A lower end of a hanger pole is mounted to an upper surface of the lower wall of the basket, and the hanger pole extends upwardly. At least one article hanger is mounted on the hanger pole. A lower end of a support is mounted to a rear end of the basket, and a first display panel is mounted on the upper end of the support. A second display panel is mounted on a front end of the basket, and a handle for pushing the smart shopping cart is attached to the upper end of the support.

The automated robotic shopping cart is a shopping cart with a controller and locomotion subsystem. The controller may provide shopping assistance to the shopper and may play audio/visual programming to entertain a child riding in the cart. The controller may wirelessly pair with a phone carried by the shopper and may use battery powered motors to propel and steer the cart such that the cart follows the shopper through a store. The battery may be recharged from a solar panel when the cart is outdoors. A GPS receiver in the controller may determine the physical location of the cart and may activate a brake if an attempt is made to remove the cart from the retail property. The invention may further comprise a reading light to illuminate products and a distress button to request assistance.

The present invention relates to a user recognition-based stroller robot and a method for controlling the same, and more particularly, to a technology for detecting and controlling states of a guardian and an infant. The user recognition-based stroller robot comprises: a detection unit configured to recognize or measure at least one of a traveling state of the stroller robot or body structures of an infant inside the stroller robot and a guardian outside the stroller robot; a controller configured to determine whether the stroller robot is controlled according to the traveling state measured by the detection unit and determine a structure change of the stroller robot according to the body structure of at least one of the infant or the guardian; and a driving unit configured to adjust at least one of a display, a belt, a seat, or a handle installed in the stroller robot according to the determination of the controller. According to the present invention, the internal configuration is automatically adjusted through each sensor of the detection unit while the guardian and the infant use the stroller robot, thereby increasing convenience.