High-performance road vehicle having: a plurality of replaceable or removable components; a control unit that supervises the operation of the road vehicle; at least one electronic identification device, which is fitted on a corresponding component, has a memory designed to contain at least one unique identifying code of the component and has a first transmission organ designed to send the data contained in the memory; and a second transmission organ designed to communicate with the first transmission organ and connected to the control unit to allow the control unit to interact with the electronic identification device.

High-performance road vehicle having: a plurality of replaceable or removable components; a control unit, which controls the operation of the road vehicle; at least one electronic identification device, which is fitted on a corresponding component, has a memory designed to contain at least one unique identifying code of the component and has a first transmission organ designed to send the data contained in the memory; and a second transmission organ, designed to communicate with the first transmission organ and connected to the control unit to allow the control unit to read the univocal identifying code of the component.

A method of processing the psychophysical state of a driver to improve the driving experience of road vehicle driven by a driver and comprising the steps of: cyclically detecting one or more objective vital parameters of the driver by means of one or more first sensors installed within a vehicular system; processing the value of a vital state index according to said one or more objective vital parameters detected; cyclically detecting one or more subjective parameters of the driver by means of one or more second sensors installed within the vehicular system; processing, starting from the objective vital parameters and according to the subjective parameters, the psychophysical state of the driver.

Disclosed is a transmission system, which is applied to a non-independent suspension or an independent suspension of a kart body. The transmission system comprises a transmission box body and a transmission wheel in the transmission box body. The transmission box body is a gear transmission box body, a sprocket and chain transmission box body, a bridge gear transmission box body or a bridge sprocket and chain transmission box body. The transmission wheel is a transmission gear or a sprocket and chain. The present invention has the following advantages: in the present invention, the power outputted from an engine can be efficiently transmitted to a drive axle, so that a vehicle can better adapt to travel on an off-road surface, and the vehicle obtains a more stable driving force; in addition, the engine is mounted separate from the drive axle, and the engine is mounted on the frame, thereby reducing the unsprung mass of the drive axle and improving the comfort of the driver and passengers.

A miniature vehicle includes a chassis frame, front and rear wheel assemblies operatively coupled at front and rear ends of the chassis frame respectively, a motorized assembly supported on the chassis frame to power the rear wheel assembly, and a foot steering arrangement operatively coupled to the front wheel assembly. Therefore, the user is able to control the miniature vehicle by the feet of the user to precisely steer and control the miniature vehicle.

A racing kart that is a travel vehicle includes a car body equipped with a seat on which a user can be seated; and a plurality of wheels which are provided to the car body. The seat is configured such that a seating face thereof is positioned lower than the top of the wheels. The car body is provided with a battery housing which is for storing a battery therein and is disposed at the rear of the seat and at a position overlapping at least a part of the seat in a rear view of the car body. The battery housing is slanted such that an upper end thereof is positioned more rearward than a lower end thereof.

Methods, systems, and vehicles are provided for mitigating turbulent air for vehicles. In accordance with one embodiment, a vehicle includes one or more downforce elements, one or more sensors, and a processor. The one or more sensors are configured to obtain one or more parameter values for the vehicle during operation of the vehicle. The processor is processor coupled to the one or more sensors, and is configured to at least facilitate determining whether turbulent air for the vehicle is likely using the parameters, and adjusting a downforce for the vehicle, during operation of the vehicle, by providing instructions for controlling the one or more downforce elements when it is determined that turbulent air for the vehicle is likely.

A road vehicle comprising a vehicle dashboard, comprising in turn an exposed surface visible from the interior of the passenger compartment; a content display device; a first projection device, which is configured to project onto the first projection surface one or more contents; at least one first aesthetic surface, also configured so as to substantially correspond to said part of the exposed surface; a support element, pivotably mounted on the vehicle dashboard and on which at least the first projection surface and the first aesthetic surface are arranged around an axis of symmetry; a movement system configured to rotate of the support element between a first configuration and a second configuration.

A method for automatic adjustment of the performance of a vehicle including the steps of detecting at least one significant physical quantity for checking the performance of the vehicle; defining at least one pair of reference indicators correlated with that physical quantity; saving at least one value of a said reference indicator in a predetermined nominal reference condition; detecting at least one value of a said reference indicator in a real operating condition of the vehicle; comparing said nominal reference indicator and real reference indicator and, if their values are different from each other, and implementing a correction of the driving power of the vehicle to compensate for the difference ascertained.

A kart includes a frame, front and rear wheels rotatable about front and rear axle axes, and an impact protection structure surrounding the frame. The impact protection structure includes: at least one front protective element, at least one rear protective element, and at least one lateral protective element on each lateral side of the kart. Each of the at least one lateral protective element is mounted to a pivot bearing fixed to the frame so as to be pivotally adjustable about a frame vertical axis, and is disposed closer to the rear axle axis than to the front axle axis. Each of the pivot bearings includes a bearing block and a bearing pedestal pivotable relative to the bearing block. Each of the at least one lateral protective element engages the bearing pedestal of a corresponding pivot bearing. Shock-absorbing dampers are disposed between the frame and the protective elements.