A vehicle includes a dynamic shock absorbing mechanism provided in a cabin. The dynamic shock absorbing mechanism includes a weight support member transversely supported at an upper portion of a cabin frame and extending along a transverse width of a vehicle body; and a weight member supported at a center portion in the vehicle body transverse width direction of the weight support member. The weight support member is an elastic member that has a smaller elastic modulus than an elastic modulus of the cabin frame.

A fuel cell vehicle capable of reducing an impact on a fuel cell stack thereof in the vehicle-width direction is provided. The fuel cell vehicle includes: the fuel cell stack; a stack frame to which the fuel cell stack is adapted to be mounted, and disposed in a front compartment of the vehicle; and a pair of front side members disposed on both the right and left sides of the stack frame and disposed to extend in the vehicle front-rear direction. The fuel cell stack is disposed so as to be fitted within the width in the vehicle-width direction of the stack frame in the vehicle-width direction. The stack frame entirely overlaps the front side members when viewed in the vehicle-width direction.

Vehicles may be composed of a relatively few number of modules that are assembled together during a final assembly process. An example vehicle may include a body module, a first drive module coupled to a first end of the body module, and a second drive module coupled to a second end of the body module. One or both of the drive modules may include a pair of wheels, a battery, an electric drive motor, and/or a heating ventilation and air conditioning (HVAC) system. One or both of the drive modules may also include a crash structure to absorb impacts. If a component of a drive module fails or is damaged, the drive module can be quickly and easily replaced with a new drive module, minimizing vehicle down time.

A fuel cell vehicle includes: a stack frame providing a fuel cell stack, the stack frame being placed in front of a vehicle cabin; and a fuel tank placed behind the stack frame. The stack frame includes a central member, a right member joined to the central member, a left member joined to the central member, and a front cross member. The front cross member is joined to front edge portions of the central member, the right member, and the left member. A front-end portion of a first joining portion between the central member and the right member and a front-end portion of a second joining portion between the central member and the left member overlap with a third joining portion of the front cross member with the front edge portions of the central member, the right member, and the left member.

There is provided a fuel cell vehicle, including a high voltage system disposed in a front compartment of the vehicle, and a first protruding portion that protrudes in a left-right direction of the vehicle toward a vehicle body of the vehicle further than a portion of the high voltage system that is closest to the vehicle body, and is fixed to the high voltage system, in which, when the vehicle is placed on a horizontal plane, the first protruding portion is arranged such that a position of a first most-protruded portion of the first protruding portion that protrudes most toward the vehicle body in a height direction is located at the same position or higher than a center of gravity of the high voltage system.

A mounting structure for a drive device includes: a power generation unit having an engine and a generator driven by the engine to generate electric power; and a drive unit having a motor for traveling and a power transmission mechanism that outputs torque from the motor toward a driving wheel. A frame member of a vehicle body is provided inside an engine compartment. The power generation unit and the drive unit are arranged, inside the engine compartment, side by side in a width direction of a vehicle so as not to contact each other, and are each connected to the frame member via a mount member. Portions of the power generation unit and the drive unit, which are close to each other in the width direction, are connected by a connecting member having an anti-vibration elastic body.

A motor vehicle with two front wheels and two rear wheels and with an electric drive that is operable via a traction energy storage device. The motor vehicle has a front recess in the region between the front wheels for a traction energy storage device assigned to the front recess, and has a rear recess in the region between the front wheels and the rear wheels, arranged in an underbody of the motor vehicle, for a traction energy storage device assigned to the rear recess, and traction energy storage devices are insertable or inserted into the recesses.

A battery for an electric drive of a motor vehicle, having a number of battery modules, which are arranged one above the other in the respective layers and accommodated in an assigned housing. The battery is optimized regarding production engineering aspects, and is also optimized regarding the requirements of tightness and accident properties, each of the layers of the battery modules arranged one above the other is accommodated in a respectively assigned, separate battery housing, which are arranged one above the other in a stack and connected to one another.

A vehicle front portion structure includes a pair of front side members arranged at a distance from each other in a vehicle width direction, each of the front side members extending in a vehicle front-rear direction, a gusset attached to a vehicle width direction outside surface of each of the front side members, protruding outwards in the vehicle width direction beyond the front side member, and having a vehicle width direction dimension decreasing toward a rear of a vehicle, and an MC cross member stretching between the front side members, in which the MC cross member and the front side member face each other in a state where the MC cross member and the front side member are apart from each other in the vehicle width direction at the same vehicle front-rear direction position as a rear end of the gusset.

An electric work vehicle includes front wheels and rear wheels for traveling, right and left machine body frames extending along a front/rear direction and an electric motor. The electric motor includes at least one of a front output shaft protruding forwards and a rear output shaft protruding rearwards. The electric motor is supported to front portions of the machine body frames to be located forwardly of the front wheels as seen in a side view.