A vehicle safety system for a vehicle includes an electronic control unit (ECU) and at least one remote crash sensor mounted in the vehicle at a location remote from the ECU and operatively connected to the ECU. The remote crash sensor is configured to sense vehicle crash conditions and to provide data related to the sensed vehicle crash conditions to the ECU. An ECU remote sensor is mounted in the vehicle at a location remote from the ECU and near a vehicle center-of-gravity (COG). The ECU remote sensor includes an inertial measurement unit (IMU), and is configured to sense vehicle roll conditions and to provide data related to the sensed vehicle roll conditions to the ECU. The ECU is operative to receive the data provided by the at least one remote crash sensor and the ECU remote sensor, perform calculations to determine whether the data is indicative of a vehicle crash condition, and to provide a signal for actuating a vehicle occupant protection device.

A recreational off-highway vehicle includes side-by-side passenger and driver seats held within a chassis. The seats sit low in the chassis and are covered by a roll cage. Grab handles are positioned on the sides of the passenger seat. Select large round tubing protects the vehicle, while rectangular tubing frames the portions of the vehicle beneath body panels. The vehicle is powered by an engine rearward of the seats that is connected to a transaxle. A radiator is positioned above the engine. A cover with an access panel is situated between the engine and the passenger seats. The vehicle is suited for rough terrain travel.

A tool holder apparatus for a motorized vehicle for residential use includes an attachment member, a rotary table attached to the attachment member, the table having fixed and relatively movable table members, and a tool holder attached to the movable table member. The attachment member removably fastens the tool holder apparatus to a member of the motorized vehicle.

An occupant safety system for a vehicle seat is disclosed. The motor vehicle seat has a seat face, a backrest that is adjacent to the seat face and a headrest that is arranged at an upper side of the backrest. At least one airbag is arranged in the headrest. The at least one airbag is constructed in such a manner that, in an inflated state, the at least one airbag prevents an occupant without any belt system from contacting a vehicle roof by acting on shoulders of an occupant in the seat.

An air-bag for a motor vehicle is formed from first and second superposed layers of fabric, each woven from a plurality of yarns. The layers of fabric are connected to each other at least partially through interweaving of the yarns of the two layers with each other. The air-bag includes at least one inflatable region, in which the two layers of fabric are substantially not connected to each other, and at least one non-inflatable region. There is a first number of crossing points of yarns that form the one layer of fabric, and there is a second number of connections between the two layers, wherein at each connection a yarn of the layer of fabric extends across to the other layer and passes over the far side of the a yarn of the other layer, and wherein the second number is no more than 0.0033 times the first number.

An airbag device for a motor vehicle, the airbag device can be provided on and secured to a seat frame and is designed to protect the head and rib cage of an occupant in the event of side impact or vehicle rollover. The airbag device has a gas generator, an airbag cushion and a first securing system, the first securing system, the gas generator and the airbag cushion being connected to one another to secure the airbag device to the seat frame. A second securing system is provided in the side region of the airbag cushion above the connecting region with the first securing system The second securing system is designed to secure the airbag cushion, with an additional securing point in the side region, to the seat frame above the first securing system.

A work vehicle includes an operator cabin, a transmission-supporting frame, and a mounting assembly. The mounting assembly includes a first mount configured to couple to the operator cabin, and a second mount configured to couple to the transmission-supporting frame. The first mount includes a first plate, and the second mount includes a second plate. The first plate and the second plate are coupled to one another at an interface, and at least one of the first plate and the second plate are configured to deform proximate to the interface to separate from one another when under tension during a roll-over event.

A rollover mitigation device for a motor vehicle comprises a frame mounted to a roof assembly within which is disposed a transversely mounted deployable rollover protector shaft. The frame comprises a pair of lateral mounting rails mounted to the roof assembly and a tubular cross member extending between the pair of lateral mounting rails. The deployable rollover protector shaft is substantially disposed within the tubular cross member when in the stowed position and is actuated from the stowed position to a locked deployed position by a spring disposed within the tubular cross member. A controller actuates a release lock to release the deployable rollover protector shaft to the deployed position upon a sensor detecting a roll angle of the motor vehicle exceeding a predetermined value. A deployment lock restrains the deployable rollover protector shaft in the deployed position.

A rollover mitigation device for a motor vehicle comprises a frame mounted to a roof assembly within which is disposed a transversely mounted deployable rollover protector shaft. The frame comprises a pair of lateral mounting rails mounted to the roof assembly and a tubular cross member extending between the pair of lateral mounting rails. The deployable rollover protector shaft is substantially disposed within the tubular cross member when in the stowed position and is actuated from the stowed position to a locked deployed position by a spring disposed within the tubular cross member. A controller actuates a release lock to release the deployable rollover protector shaft to the deployed position upon a sensor detecting a roll angle of the motor vehicle exceeding a predetermined value. A deployment lock restrains the deployable rollover protector shaft in the deployed position.

An anti-rollover system and method for mitigating vehicle rollover. The system having a plurality of anti-rollover devices positioned around the vehicle chassis and being operable to calculate the likelihood of a vehicle rollover and determine the attitude of rollover there by actuating the anti-rollover device to counter roll thereby preventing a rollover collision.