An embodiment floor structure of a vehicle includes a pair of side seals disposed to face each other in a vehicle width direction, and respectively disposed in a vehicle length direction, a floor frame disposed between the pair of side seals and including a pair of longitudinal frames respectively arranged along the pair of side seals and at least one transverse frame mounted between the pair of longitudinal frames in the vehicle width direction, and at least one core structural member disposed in a space provided by the floor frame and including a material for absorbing impact.

An embodiment floor structure of a vehicle includes a pair of side seals disposed to face each other in a vehicle width direction, and respectively disposed in a vehicle length direction, a floor frame disposed between the pair of side seals and including a pair of longitudinal frames respectively arranged along the pair of side seals and at least one transverse frame mounted between the pair of longitudinal frames in the vehicle width direction, and at least one core structural member disposed in a space provided by the floor frame and including a material for absorbing impact.

A radio-controlled vehicle having a frame, a left undercarriage and a right undercarriage; wherein the frame has a front guide and a rear guide, each configured to house a respective cylinder; each undercarriage having a front slide and a rear slide, which are connected in a sliding manner to the front guide and to the rear guide, respectively; wherein each cylinder is configured to selectively vary the distance between the longitudinal axis of the frame and the longitudinal axis of each undercarriage; wherein each undercarriage comprises an anti-derailment plate.

A radio-controlled vehicle having a frame, a left undercarriage and a right undercarriage; wherein the frame has a front guide and a rear guide, each configured to house a respective cylinder; each undercarriage having a front slide and a rear slide, which are connected in a sliding manner to the front guide and to the rear guide, respectively; wherein each cylinder is configured to selectively vary the distance between the longitudinal axis of the frame and the longitudinal axis of each undercarriage; wherein each undercarriage comprises an anti-derailment plate.

Disclosed is a self-balancing device for self-propelled off-road RV box body. The self-balancing device includes an auxiliary beam body for connecting with a bottom end of the RV box body, a front triangular balance beam body, a rear triangular balance beam body and an axle-holding device for connecting with a RV chassis girder. The front triangular balance beam body and the rear triangular balance beam body are arranged close to both ends of the auxiliary beam body respectively. The axle-holding device is arranged between the front triangular balance beam body and the rear triangular balance beam body. Both the front triangular balance beam body and the rear triangular balance beam body include a hard limit structure for limiting a swing angle of the RV box body. The axle-holding device includes a soft limit structure for horizontally resetting the RV box body.

A vehicle front section structure including left and right front side frames, and left and right front side members. The left and right front side frames extend along a vehicle front-rear direction at respective sides in a vehicle width direction with respect to the power unit. A lower kick section sloping with a downward gradient on progression toward a vehicle rear side is formed at a rear section of each of the front side frames. The left and right front side members extend along the vehicle front-rear direction at a vehicle upper side of the left and right front side frames, are supported by the left and right front side frames, and configure part of a vehicle body. An upper kick section sloping with a downward gradient on progression toward the vehicle rear side is formed at a rear section of each of the front side members.

A vehicle front section structure includes left and right front side frame. A deformation portion configured to undergo compression deformation in the vehicle front-rear direction at a time of head-on collision of the vehicle is provided at a front end portion of each of the left and right front side frames. Left and right front side members that support a floor section of a vehicle cabin extend along the vehicle front-rear direction at a vehicle upper side with respect to the left and right front side frames. Front sections of the left and right front side members and the corresponding left and right deformation portions are connected by left and right coupling members. The left and right coupling members are configured so as to more readily undergo plastic deformation under collision load at a time of head-on collision than the left and right front side members.

A vehicle front section structure includes: a power unit installed at a front section; a left and right pair of front side frames extending in a vehicle front-rear direction; a left and right pair of front side members extending in the vehicle front-rear direction at a vehicle upper side of the left and right pair of front side frames, with rear end portions of the front side members being respectively joined to the left and right pair of front side frames; a cross member disposed at a vehicle rear side and obliquely upward of the power unit so as to span between the left and right pair of front side members and to support a driving seat of the vehicle; and a reinforcement brace spanning between the cross member and at least one front side member of the left front side member or a right front side member.

A reinforcing member for cold forming according to an embodiment comprises: a blank member; and a reinforcing patch member provided to cover at least a portion of the blank member and coupled to the blank member by a plurality of welded portions, wherein the entire region of a heat-affected zone formed around the welded portions in the blank member is positioned in a region corresponding to the reinforcing patch member, and a heat-affected zone formed around a first welded portion from among the welded portions may contact the central point of a second welded portion adjacent to the first welded portion or may be formed to be spaced apart from the central point of the second welded portion.

A frame assembly for a motor vehicle that may include a first load beam, a second load beam, and a frame rail that are configured for receipt and transfer of energy to a sill that can move the sill in a downward direction. A counterbalancing load beam that includes a first fixed end is attached to the first load beam and a second fixed end is attached to the frame rail. The counterbalancing load beam is configured for receipt of at least a portion of the energy applied to the first load beam, and the counterbalancing load beam is configured to transfer the energy received from the first load beam to the frame rail such that the transfer of energy to the sill that can move the sill in the downward direction is counterbalanced by the energy transferred by the counterbalancing load beam to the frame rail.