A tilting system for a suspended cab of a work vehicle includes a hydraulic cylinder coupled to a chassis of the work vehicle at a first end and the suspended cab at a second end. Further, the hydraulic cylinder is configured to extend to drive the suspended cab to rotate from a lowered position to a raised position. In addition, the hydraulic cylinder is configured to be substantially horizontal while the suspended cab is in the lowered position.

A tilting system for a suspended cab of a work vehicle includes a hydraulic cylinder coupled to a chassis of the work vehicle at a first end and the suspended cab at a second end. Further, the hydraulic cylinder is configured to extend to drive the suspended cab to rotate from a lowered position to a raised position. In addition, the hydraulic cylinder is configured to be substantially horizontal while the suspended cab is in the lowered position.

A system for automatic tilting of an operator cabin of a work machine includes a first sensor that generates a first signal indicative of a first pitch angle of a frame structure relative to a non-inclined surface. The system also includes a tilting mechanism to tilt the operator cabin relative to the frame structure. The system further includes a controller that receives the first signal indicative of the first pitch angle. The controller determines a second pitch angle based on the first pitch angle. The controller controls first and second actuators to tilt the operator cabin by the second pitch angle relative to the non-inclined surface. The second pitch angle is opposite in direction to the first pitch angle. Further, based on a tilting of the operator cabin, a plane defined by the operator cabin is substantially parallel to the non-inclined surface.

A system for automatic tilting of an operator cabin of a work machine includes a first sensor that generates a first signal indicative of a first pitch angle of a frame structure relative to a non-inclined surface. The system also includes a tilting mechanism to tilt the operator cabin relative to the frame structure. The system further includes a controller that receives the first signal indicative of the first pitch angle. The controller determines a second pitch angle based on the first pitch angle. The controller controls first and second actuators to tilt the operator cabin by the second pitch angle relative to the non-inclined surface. The second pitch angle is opposite in direction to the first pitch angle. Further, based on a tilting of the operator cabin, a plane defined by the operator cabin is substantially parallel to the non-inclined surface.

A vehicle includes a support assembly extending between a chassis and a cab. The support assembly includes a first bracket coupled to the chassis, a second bracket coupled to the cab, a stay arm having a first end coupled to the first bracket and an opposing second end, and a locking assembly. The stay arm defines a locking interface between the first end and the opposing second end. The locking assembly includes a slide, an actuator, a release arm, and a pawl. The slide is translatable along the stay arm. The slide defines a first interface coupled to the second bracket, a second interface coupled to the actuator, and a third interface. The release arm is coupled to the actuator and the third interface. The pawl is coupled to release arm at the third interface. The pawl selectively engages with the locking interface based on a configuration of the actuator.

A vehicle includes a support assembly extending between a chassis and a cab. The support assembly includes a first bracket coupled to the chassis, a second bracket coupled to the cab, a stay arm having a first end coupled to the first bracket and an opposing second end, and a locking assembly. The stay arm defines a locking interface between the first end and the opposing second end. The locking assembly includes a slide, an actuator, a release arm, and a pawl. The slide is translatable along the stay arm. The slide defines a first interface coupled to the second bracket, a second interface coupled to the actuator, and a third interface. The release arm is coupled to the actuator and the third interface. The pawl is coupled to release arm at the third interface. The pawl selectively engages with the locking interface based on a configuration of the actuator.

A lock mechanism for a tiltable operator cab of a machine is provided. The lock mechanism includes a first bracket which receives a first engagement member of the operator cab. The operator cab is pivotably coupled to an end of the machine. A second bracket receives a second engagement member of the operator cab. The second bracket is located at an offset spaced apart from the first bracket. The lock mechanism includes a sliding member having a first locking pin and a second locking pin. The sliding member slides between a first position and a second position. When the sliding member is in the first position, the first locking pin locks the first bracket with the first engagement member, and the second locking pin locks the second bracket with the second engagement member such that the sliding member locks a tilt motion of the operator cab.

A lock mechanism for a tiltable operator cab of a machine is provided. The lock mechanism includes a first bracket which receives a first engagement member of the operator cab. The operator cab is pivotably coupled to an end of the machine. A second bracket receives a second engagement member of the operator cab. The second bracket is located at an offset spaced apart from the first bracket. The lock mechanism includes a sliding member having a first locking pin and a second locking pin. The sliding member slides between a first position and a second position. When the sliding member is in the first position, the first locking pin locks the first bracket with the first engagement member, and the second locking pin locks the second bracket with the second engagement member such that the sliding member locks a tilt motion of the operator cab.

An electric actuator includes: a drive part (2); a motion conversion mechanism part (3) configured to convert a rotary motion from the drive part (2) to a linear motion in an axial direction parallel with an output shaft (10a) of the drive part (2); a driving force transmission part (4) including a transmission gear mechanism (28) configured to transmit a driving force from the drive part (2) to the motion conversion mechanism part (3); and a motion-conversion-mechanism support part (5) including a double-row bearing (40) configured to support the motion conversion mechanism part (3), wherein the double-row bearing (40) is arranged on one side in the axial direction with respect to the transmission gear mechanism (28).

An electric actuator includes: a drive part (2); a motion conversion mechanism part (3) configured to convert a rotary motion from the drive part (2) to a linear motion in an axial direction parallel with an output shaft (10a) of the drive part (2); a driving force transmission part (4) including a transmission gear mechanism (28) configured to transmit a driving force from the drive part (2) to the motion conversion mechanism part (3); and a motion-conversion-mechanism support part (5) including a double-row bearing (40) configured to support the motion conversion mechanism part (3), wherein the double-row bearing (40) is arranged on one side in the axial direction with respect to the transmission gear mechanism (28).