An embodiment mobility includes a frame unit, a traveling drive unit disposed at a front or rear side of the frame unit and including a traveling wheel and a suspension module configured to change a position of the traveling wheel relative to the frame unit, and a suspension assistant unit having a first side coupled to the frame unit and a second side coupled to the suspension module, the suspension assistant unit including a wire member configured to pull the suspension module and having a first side coupled to the suspension module.

The present invention relates to all terrain vehicles having at least a pair of laterally spaced apart seating surfaces.

The present invention relates to all terrain vehicles having at least a pair of laterally spaced apart seating surfaces.

A lawnmower includes a frame, a pair of drive wheels, a front axle assembly, a first caster wheel, a second caster wheel, a first rod, a second rod, and a mower deck. The pair of drive wheels are coupled to a second end portion of the frame. The front axle assembly includes a bar pivotally coupled to a first end portion of the frame about a pivot axis. The first caster wheel is coupled to a first lateral end of the bar. The second caster wheel is coupled to a second lateral end of the bar. The first rod is coupled between the frame and the first lateral end of the bar. The second rod is coupled between the frame and the second lateral end of the bar. When the bar pivots about the pivot axis, the first caster wheel and the second caster wheel move relative to the frame.

A lawnmower includes a frame, a pair of drive wheels, a front axle assembly, a first caster wheel, a second caster wheel, a first rod, a second rod, and a mower deck. The pair of drive wheels are coupled to a second end portion of the frame. The front axle assembly includes a bar pivotally coupled to a first end portion of the frame about a pivot axis. The first caster wheel is coupled to a first lateral end of the bar. The second caster wheel is coupled to a second lateral end of the bar. The first rod is coupled between the frame and the first lateral end of the bar. The second rod is coupled between the frame and the second lateral end of the bar. When the bar pivots about the pivot axis, the first caster wheel and the second caster wheel move relative to the frame.

An anti-roll wheel suspension system for vehicles includes a first suspension spring and a first damper arranged to be connected to a first wheel, and a second suspension spring and a second damper arranged to be connected to a second wheel. The system further includes a centre part operatively connected to the first suspension spring and the first damper, and operatively connected to the second suspension spring and the second damper. The centre part is arranged between the first suspension spring and the second suspension spring, and between the first damper and the second damper. The centre part is movably arranged in a transverse direction. The centre part, when moving in the transverse direction upon activation from the first wheel and/or the second wheel, is configured for impacting the stiffness of the first suspension spring and/or the second suspension spring.

An anti-roll wheel suspension system for vehicles includes a first suspension spring and a first damper arranged to be connected to a first wheel, and a second suspension spring and a second damper arranged to be connected to a second wheel. The system further includes a centre part operatively connected to the first suspension spring and the first damper, and operatively connected to the second suspension spring and the second damper. The centre part is arranged between the first suspension spring and the second suspension spring, and between the first damper and the second damper. The centre part is movably arranged in a transverse direction. The centre part, when moving in the transverse direction upon activation from the first wheel and/or the second wheel, is configured for impacting the stiffness of the first suspension spring and/or the second suspension spring.

Disclosed herein is a coupled torsion beam axle type rear suspension system that includes a coupled torsion beam axle (100) installed to extend in a transverse direction of a vehicle body, a pair of trailing arms (200) coupled to respective ends of the coupled torsion beam axle (100), and a transverse leaf spring (300) having both ends connected to the respective trailing arms (200) and a center portion connected to a body cross member (40), thereby reducing the number of parts and improving driving stability.

Disclosed herein is a coupled torsion beam axle type rear suspension system that includes a coupled torsion beam axle (100) installed to extend in a transverse direction of a vehicle body, a pair of trailing arms (200) coupled to respective ends of the coupled torsion beam axle (100), and a transverse leaf spring (300) having both ends connected to the respective trailing arms (200) and a center portion connected to a body cross member (40), thereby reducing the number of parts and improving driving stability.

A suspension assembly for a commercial vehicle includes a first linkage, an air spring, a carriage, and a second linkage. The first linkage is pivotally coupled at a first end with a structural member of a frame. The structural member extends downwards from the frame. The air spring is coupled with the frame and a second end of the first linkage. The air spring drives the first linkage to pivot about the first end relative to the structural member. The carriage is pivotally coupled with the first linkage at a position between the first end and the second end of the first linkage. The second linkage is pivotally coupled at a first end with the structural member, and pivotally coupled with the carriage at a second end. The structural member, the first linkage, the second linkage, and the carriage define a four-bar linkage.