Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.

Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.

A support member has a first wing plate and a second wing plate coupled to the first wing plate to be pivotable relative to the first wing plate. A fixing member fixes the first wing plate to an opening member from an external space external to an operator's compartment and is also removed from the first wing plate to allow the first wing plate and the opening member to be unfixed. A fixing member fixes the second wing plate to a panel from an internal space of the operator's compartment and is also removed from the panel to allow the second wing plate and the panel to be unfixed.

A support member has a first wing plate and a second wing plate coupled to the first wing plate to be pivotable relative to the first wing plate. A fixing member fixes the first wing plate to an opening member from an external space external to an operator's compartment and is also removed from the first wing plate to allow the first wing plate and the opening member to be unfixed. A fixing member fixes the second wing plate to a panel from an internal space of the operator's compartment and is also removed from the panel to allow the second wing plate and the panel to be unfixed.

Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.

Disclosed is an electric vehicle, comprising a chassis (1), a vehicle body and a power battery (71), wherein the chassis (1) comprises a frame system (2), a steering motor damping system (13) mounted on the frame system (2), a wheel system (12) connected to the steering motor damping system (13), a steering system (3) mounted on the frame system (2), and a braking system (4) mounted on the frame system (2); and the wheel system (12) comprises a left front wheel (121) using a hub motor, a left rear wheel (123) using a hub motor, a right front wheel (122) using a hub motor, and a right rear wheel (124) using a hub motor. Driving the wheels (121, 122, 123, 124) with the hub motors can omit a traditional mechanical transmission system, so as to simplify the structure of the chassis (1) and reduce the weight of the chassis (1). Compared with a traditional electric vehicle, the electrical vehicle has a lighter weight, smaller volume, reduced mechanical transmission loss, and improved electrical energy utilization rate.

An emergency exit arrangement for a vehicle and or a building comprising of a plurality of spring pressured stud assembly having a plurality of locking pin in the upper region connected correspondingly to a plurality of rope which is connected to a first pulling device; a plurality of locking pin in the lower region connected correspondingly to a plurality of rope which is connected to a second pulling device. Sequential pulling of the first and the second pulling device ejects out the aperture cover. The pulling devices are electrical, operated by pressing a button; or through temperature sensor, impact sensor, pressure sensor, smoke sensor and or a combination thereof. The pulling devices are alternatively rotatable knobs. The aperture cover is easily mountable.

An emergency exit arrangement for a vehicle and or a building comprising of a plurality of spring pressured stud assembly having a plurality of locking pin in the upper region connected correspondingly to a plurality of rope which is connected to a first pulling device; a plurality of locking pin in the lower region connected correspondingly to a plurality of rope which is connected to a second pulling device. Sequential pulling of the first and the second pulling device ejects out the aperture cover. The pulling devices are electrical, operated by pressing a button; or through temperature sensor, impact sensor, pressure sensor, smoke sensor and or a combination thereof. The pulling devices are alternatively rotatable knobs. The aperture cover is easily mountable.

An emergency release mechanism for a non-openable window arranged in a frame, the release mechanism includes a handle having a first end releasably attachable to a lower end of the window, wherein the handle is arranged to be attached to the frame and to be rotated about an axis of rotation which is substantially parallel to a bottom edge of the window, wherein the point of attachment between the handle and the window is offset from the axis of rotation of the handle such that an upwards rotation of the handle causes a substantially concomitant downward and outward movement of the window in relation to the frame.

An emergency release mechanism for a non-openable window arranged in a frame, the release mechanism includes a handle having a first end releasably attachable to a lower end of the window, wherein the handle is arranged to be attached to the frame and to be rotated about an axis of rotation which is substantially parallel to a bottom edge of the window, wherein the point of attachment between the handle and the window is offset from the axis of rotation of the handle such that an upwards rotation of the handle causes a substantially concomitant downward and outward movement of the window in relation to the frame.