A wheeled carrying apparatus includes a standing frame, a handle frame, a wheel mount, a locking assembly and a release mechanism. The handle frame is rotatable between a first and a second position of different inclinations. The wheel mount carries a wheel and is rotatable relative to the standing frame for changing an orientation of the wheel axis. The locking assembly includes a wheel mount latch adapted to engage and rotationally lock the wheel mount relative to the standing frame, and to disengage and unlock the wheel mount. The release mechanism includes an operating part carried with the handle frame and is configured so that the operating part is operable to cause the wheel mount latch to disengage the wheel mount when the handle frame is in the first position, the operating part being operatively decoupled from the wheel mount latch when the handle frame is in the second position.

A stroller and foldable frame assembly for a stroller includes a locking mechanism adjustable between a locked position and an unlocked position. The locking mechanism is configured to releasably lock the foldable frame assembly in its use configuration and/or storage configuration by releasably and internally locking at least one of a respective swivel joint assembly of the frame assembly. The locking mechanism includes an actuation element configured to adjust the locking mechanism between the unlocked and the locked position that is arranged spaced apart transversely to a swivel axis of the respective at least one internally lockable swivel joint.

A braking mechanism and a child stroller, where the braking mechanism includes a pedal part and a housing part connected to the pedal part, the housing part has two side walls and a middle wall sandwiched between the two side walls, a locking end is arranged on an outer side of each of the side walls, and a sliding groove is arranged on an inner surface of the middle wall, where the braking mechanism is further provided with an elastic piece part, the elastic piece part is provided with a highest point, and the braking mechanism is prevented from a false locking through a cooperation of the sliding groove and the highest point. The braking mechanism according to the disclosure has a function of preventing false locking, which can avoid a false locking phenomenon of the child stroller and improve the safety of the child stroller in use.

Provided are a multi-functional perambulator, a multi-functional cradle bed, a multi-functional infanette and a multi-functional baby carriage, wherein same are all mounted with spring clamping slots (80, 3319). Also provided is a novel multi-wheel walking device. Further provided are a smart wrist band and a smart watch, wherein both of same have a real-time payment system, may be used for a user of a perambulator, a cradle bed, a multi-functional infanette and a multi-functional baby carriage to make a payment when shopping in various supermarkets, facilitates shopping for the user, and satisfies the requirements of the user.

Provided are a multi-functional perambulator, a multi-functional cradle bed, a multi-functional infanette and a multi-functional baby carriage, wherein same are all mounted with spring clamping slots (80, 3319). Also provided is a novel multi-wheel walking device. Further provided are a smart wrist band and a smart watch, wherein both of same have a real-time payment system, may be used for a user of a perambulator, a cradle bed, a multi-functional infanette and a multi-functional baby carriage to make a payment when shopping in various supermarkets, facilitates shopping for the user, and satisfies the requirements of the user.

The present disclosure relates to a smart stroller and a method of controlling the same. The smart stroller includes a sensor part for sensing various information regarding a space in which a baby is seated and information regarding the surrounding environment in which the smart stroller is traveling. The sensed information is transmitted to a controller so as to be calculated as information for controlling operation of the smart stroller or information for informing to a user. This may enable the smart stroller to travel in a stable manner. This may also allow the user to check the state of the baby in real time and take necessary action.

The present disclosure relates to a smart stroller and a method of controlling the same. The smart stroller includes a sensor part for sensing various information regarding a space in which a baby is seated and information regarding the surrounding environment in which the smart stroller is traveling. The sensed information is transmitted to a controller so as to be calculated as information for controlling operation of the smart stroller or information for informing to a user. This may enable the smart stroller to travel in a stable manner. This may also allow the user to check the state of the baby in real time and take necessary action.

The disclosure relates to a brake system for a baby or child vehicle, and more particularly, to a brake system for a baby or child vehicle, in which the movement of the vehicle is controlled by locking a brake while an occupant is getting off the vehicle, and automatically releasing the brake in only a case where it is checked that the occupant is getting on the vehicle, thereby preventing a falling accident caused by the movement of the vehicle when the occupant gets on or off the vehicle or while a toddler stands up on the vehicle.

A stroller can include a body having a pair of driving wheels mounted to left and right sides thereof; a motor configured to rotate the pair of driving wheels; a frame comprising a lower part connected to the body, the frame extending upwards from the lower part; a handle connected to the frame; a sensor unit including a force detection sensor configured to detect force applied to the handle, a touch sensor configured to detect whether the handle is being grasped, and a wheel sensor configured to detect rotation of the pair of driving wheels; and a controller configured to calibrate the force detection sensor based on data detected by the touch sensor and the wheel sensor.

A cart can include a body having driving wheels mounted to left and right sides thereof; a motor configured to rotate the driving wheels; a frame comprising a lower part connected to the body, the frame extending upwards from the lower part; a handle connected to the frame; a sensor unit including a tilt sensor configured to detect a tilt of the body, and a touch sensor configured to detect whether the handle is grasped; and a controller configured to in response to determining that the handle is not grasped based on data detected by the touch sensor, determine whether the cart is located on a slope based on data detected by the tilt sensor, change a control parameter of the motor based on whether the cart is located on the slope and perform a braking operation in different ways based on whether the motor is rotating.