A working machine includes a travel device, a motive power transmission device configured to transmit a motive power to the travel device, a transmission case configured to house the motive power transmission device, and a hydraulic operation fluid tank disposed on an upper surface of the transmission case.

A working vehicle is provided with a traveling vehicle, a working section which is supported on a rotatable base, an operator's cab, and a connection section. The connection section includes: a connection section body which connects the rotatable base and the operator's cab and which is provided so as to be capable of pivoting about a base-side connection section connected to the rotatable base and about the operator's cab-side connection section connected to the operator's cab; and a pivot control section which extends so as to always intersect the connection section body in the range of pivoting of the connection section body, connects the rotatable base and the operator's cab, and is provided so as to be capable of pivoting about a base-side connection section connected to the rotatable base and about an operator's cab-side connection section connected to the operator's cab.

A working machine includes a travel device, a motive power transmission device configured to transmit a motive power to the travel device, a transmission case configured to house the motive power transmission device, and a hydraulic operation fluid tank disposed on an upper surface of the transmission case.

A working machine includes a travel device, a motive power transmission device configured to transmit a motive power to the travel device, a transmission case configured to house the motive power transmission device, and a hydraulic operation fluid tank disposed on an upper surface of the transmission case.

The present disclosure relates to a structure for mounting an upper cabin suspension bracket, the structure configured to connect the upper cabin suspension bracket to a main sill front, wherein an upper cabin suspension bracket mount member for mounting the upper cabin suspension bracket is fixed to integrally form a closed curved surface from the bottom of the main sill front to a front side of a dash member.

The present disclosure relates to a structure for mounting an upper cabin suspension bracket, the structure configured to connect the upper cabin suspension bracket to a main sill front, wherein an upper cabin suspension bracket mount member for mounting the upper cabin suspension bracket is fixed to integrally form a closed curved surface from the bottom of the main sill front to a front side of a dash member.

The present invention relates to a device for a vehicle cab of a vehicle, said vehicle cab comprising a cab module configured for attachment to a chassis beam via a support device arranged to support said cab module, said support device comprising rotation means for rotation of said vehicle cab, wherein said support device comprises elevation means for raising/lowering of said cab module. The present invention also relates to a vehicle with a device for a vehicle cab.

The present invention relates to a device for a vehicle cab of a vehicle, said vehicle cab comprising a cab module configured for attachment to a chassis beam via a support device arranged to support said cab module, said support device comprising rotation means for rotation of said vehicle cab, wherein said support device comprises elevation means for raising/lowering of said cab module. The present invention also relates to a vehicle with a device for a vehicle cab.

Aspects of the disclosure relate to a mechanical joint with five degrees of freedom. In certain embodiments, the mechanical joint includes first and second triangular linkages. The first triangular linkage includes a base end configured to hingedly couple to a first body to pivot relative to the first body and a vertex end that includes a first rotational member. The second triangular linkage includes a base end configured to hingedly couple to a second body to pivot relative to the second body and a vertex end that includes a second rotational member. The first rotational member and the second rotational member are rotationally coupled to form a all joint. With this joint, the second body is moveable in two translational degrees of freedom and restricted in one translational degree of freedom relative to the first body. Such a configuration allows vertical movement and/or reduces stress on the joint.

Aspects of the disclosure relate to a mechanical joint with five degrees of freedom. In certain embodiments, the mechanical joint includes first and second triangular linkages. The first triangular linkage includes a base end configured to hingedly couple to a first body to pivot relative to the first body and a vertex end that includes a first rotational member. The second triangular linkage includes a base end configured to hingedly couple to a second body to pivot relative to the second body and a vertex end that includes a second rotational member. The first rotational member and the second rotational member are rotationally coupled to form a all joint. With this joint, the second body is moveable in two translational degrees of freedom and restricted in one translational degree of freedom relative to the first body. Such a configuration allows vertical movement and/or reduces stress on the joint.