The Kinetic Kar will have a large high pressure chamber filled with hydraulic fluid pressured up to 20 ton for the initial motion of the car. The pressure harvested by means of pumps, pistons, valves, and electrical gadget will be too high for the high pressure chamber. It is estimated that the car will move from zero to 20 miles in a matter of 2 seconds and run at up to 150 miles per hour for a mile before pressure tank is depleted totally. It will only take 3-4 seconds for pressure reservoir to replenish.

The Kinetic Kar will have a large high pressure chamber filled with hydraulic fluid pressured up to 20 ton for the initial motion of the car. The pressure harvested by means of pumps, pistons, valves, and electrical gadget will be too high for the high pressure chamber. It is estimated that the car will move from zero to 20 miles in a matter of 2 seconds and run at up to 150 miles per hour for a mile before pressure tank is depleted totally. It will only take 3-4 seconds for pressure reservoir to replenish.

A frame structure for a vehicle includes: an inner panel connected to a side member and defining an inner side of a rear part of the side member; an outer panel connected to a rear side of the side member and coupled to an outer side of the inner panel defining a closed cross-section together with the inner panel and defining an outer side of the rear part of the side member; an opening portion formed below the inner and outer panels partially opening the closed cross-section so that a front end of a rear suspension arm can be inserted into the opening portion; and a reinforcing member disposed in the opening portion defining the closed cross-section together with the outer panel and the inner panel and configured to close an internal space in the outer and inner panels.

A frame structure for a vehicle includes: an inner panel connected to a side member and defining an inner side of a rear part of the side member; an outer panel connected to a rear side of the side member and coupled to an outer side of the inner panel defining a closed cross-section together with the inner panel and defining an outer side of the rear part of the side member; an opening portion formed below the inner and outer panels partially opening the closed cross-section so that a front end of a rear suspension arm can be inserted into the opening portion; and a reinforcing member disposed in the opening portion defining the closed cross-section together with the outer panel and the inner panel and configured to close an internal space in the outer and inner panels.

A system and method for calibrating and controlling an active dampening system for a chassis of a vehicle having an engine involve operating the engine in a cylinder deactivation mode and, during the cylinder deactivation mode, (i) receiving, from a set of sensors, measured vibrations on first and second frame rails of the chassis, (ii) generating control signals for a set of actuators based on the measured vibration of the first and second frame rails, each actuator being configured to generate a vibrational force in at least one direction, and (iii) outputting, to the set of actuators, the control signals, wherein receipt of the control signals cause the set of actuators to generate vibrational forces that dampen the vibration of the first and second frame rails, respectively, to decrease noise/vibration/harshness (NVH).

Provided are an adjusting base and a self-driven robot. The flexible base includes: a chassis, a carrying plate and an adjusting mechanism. The bottom of the chassis is provided with at least one second driven wheel and at least two driving wheels. The bottom of the carrying plate is provided with at least a first driven wheel. The adjusting mechanism is configured to connect to the carrying plate and the chassis or connect to the carrying plate and the second driven wheel. When the ground is uneven, the adjusting mechanism is configured to dynamically adjust the second driven wheel in such a manner that the first driven wheel, the second driven wheel and the driving wheels are in contact with the ground.

Provided are an adjusting base and a self-driven robot. The flexible base includes: a chassis, a carrying plate and an adjusting mechanism. The bottom of the chassis is provided with at least one second driven wheel and at least two driving wheels. The bottom of the carrying plate is provided with at least a first driven wheel. The adjusting mechanism is configured to connect to the carrying plate and the chassis or connect to the carrying plate and the second driven wheel. When the ground is uneven, the adjusting mechanism is configured to dynamically adjust the second driven wheel in such a manner that the first driven wheel, the second driven wheel and the driving wheels are in contact with the ground.

A suspension mechanism has a tube member that is movably attached to an attachment shaft and includes an outer peripheral surface of approximately hemispherical shape, a first attachment shaft retaining member provided on the chassis to swingably retain the attachment shaft with an outer peripheral surface of the tube member abutted on its inside surface, a shaft lower end portion of slip surface shape provided at lowermost part of the attachment shaft, a second attachment shaft retaining member provided on the chassis below the first attachment shaft retaining member and having a vertex equivalent section of approximately conical shape and a slope equivalent section to retain the attachment shaft with the slip surface shape shaft lower end portion abutted onto the vertex equivalent section or the slope equivalent section, and a biasing member that biases the tube member and the shaft lower end portion away from each other.

A motor vehicle has a chassis and a passenger cell which is mounted on the chassis by way of vibration-damping connection elements. The chassis forms an undercarriage with at least two front wheels mutually spaced in the transverse direction of the vehicle and at least two rear wheels mutually spaced in the transverse direction of the vehicle, and with at least one drive device. The chassis is provided with front and rear energy-absorbing deformation elements of a front and rear bumper structure, respectively.

A suspension system for controlling multiple degrees of freedom of a cab of a vehicle has mounting pads that support the cab with a spring assembly connected between the chassis and each mounting pad, allowing the cab to move with multiple degrees of freedom. A lateral rod connects with one of the mounting pads, with the chassis, and restricts sideways motion of the cab. A longitudinal rod connects with one of the mounting pads, with the chassis, and restricts forward motion of the cab. A stabilizer bar connects with one of the front mounting pads, one of the rear mounting pads, the chassis structure, and controls forward pitch rate of the cab. A roll control bar connects with the rear mounting pads and the chassis structure, and controls lateral roll rate of the cab.