A bumper assembly for a material handling vehicle is provided. The material handling vehicle includes a vehicle frame. The bumper assembly includes a first bumper coupled to a first side of the vehicle frame and having a first slot extending along a portion of the first bumper and a first protruding portion. The first protruding portion extends outwardly at an angle past a plane defined by the first side of the vehicle frame. The bumper assembly further includes a second bumper coupled to a second side of the vehicle frame opposite to the first side and having a second slot extending along a portion of the second bumper and a second protruding portion. The second protruding portion extends outwardly at an angle past a plane defined by the second side of the vehicle frame.

A front hood assembly for a vehicle including a front grille may include a sensory assembly, a bumper assembly positioned adjacent to the front grille, and an energy absorber structure. The bumper assembly may include a bumper reinforcement having a front face and a top face, which front face is disposed below and extends away from the top face. The energy absorber structure may be positioned adjacent to the top face of the bumper reinforcement. The energy absorber structure may be rearwardly compliant in an impact direction and disposed below and rearwardly of the sensory assembly such that an impact of the sensory assembly with the energy absorber structure in the impact direction collapses the energy absorber structure rearwardly.

An apparatus, system and method capable of providing a bumper capable of providing decreasing reversionary impact forces upon an impacting collider as the bumper is compressed. The apparatus, system and method may include at least a bumper cover; and a scissor mechanism housed within the bumper cover. The scissor mechanism may comprise a forward extension member proximal and having a parallel axis that is at least substantially parallel to a parallel tangential axis of the bumper cover; a rear extension member substantially parallel to the forward extension member, and distal from the flexible bumper; at least left and right long scissor members that are rotatably and slidably associated with respective slots in the forward extension member, and that, are rotatably associated with the rear extension member; and at least left and right short scissor members that are rotatably associated with the front extension member, and that are rotatably associated with a respective one of the left and right long scissor members.

An object-sensing bumper extension comprises a durable and flexible material. The bumper extension is connected to the bumper of a vehicle such as a lift truck to detect encroachment and/or impact between the vehicle and an operator or other object. A non-contact sensor detects encroachment of an object within an impact danger zone arranged immediately in front of and near the sides of the vehicle. An impact sensor detects impact between the vehicle and an object. A control system receives sensor signals and initiates a reaction operation of the vehicle in response to sensor activity. The reaction operation can include slowing the vehicle down, stopping the vehicle, and/or reversing the vehicle. The bumper extension can include a plurality of outwardly angled, substantially parallel ridges that deform outwardly and downwardly to push an impacted object away from danger and to fill a gap between the vehicle and the ground.

A vehicle trim assembly includes a first trim component having an interior facing surface and an exterior facing surface, the first trim component including an extended portion, a second trim component including an edge defining a groove configured to engage with the extended portion of the first trim component, and a single chip sensor overmolded with the second trim component such that the single chip sensor is integrated into the second trim component. The single chip sensor is formed with the second trim component in a multi-shot injection molding process.

An ultrasonic sensor includes a sensor body, a cushion member, a retainer unit, and a drainage path. The sensor body includes an ultrasonic microphone and a microphone support unit which allows a protruding part of the ultrasonic microphone located at a distal end in an axial direction to protrude and supports the protruding part. The cushion member covers the protruding part. The retainer unit allows exposure of a portion of the cushion member that is located at the distal end in the axial direction, and a portion of the cushion member that is located at a proximal end in the axial direction is sandwiched between the retainer unit and an outer peripheral surface of the protruding part. The drainage path penetrates the retainer unit in a radial direction to allow water to be discharged out of the retainer unit from a gap between the retainer unit and the cushion member.

A sensor mounting structure includes: a sensor body that detects peripheral information in relation to a vehicle; and a housing that is formed in a box shape, covers the sensor body from an outer side, and is attached to an outer panel of the vehicle, wherein fastening portions extend from wall surfaces of the housing at one end side and another end side in a direction along the outer panel, and the fastening portions are fastened to the outer panel by fastening members.

A sensor arrangement for a vehicle includes a holding device holding a sensor and a connection arrangement connecting a holding device to a vehicle component. The connection arrangement moves the holding device between an operating position and at least one protecting position. The connection arrangement includes at least one lever arrangement that moves the holding device from the operating position to the at least one protecting position in response to an application of a collision force against the vehicle such that the holding device moves in at least one spatial direction including a first spatial direction, which corresponds to a first force component of the collision force. The connection arrangement includes at least one restoring arrangement that generates a restoring force applied against the at least one lever arrangement to move the holding device from the protecting position back to the operating position.

In an external sensor attachment portion structure of the present invention, an external sensor includes: a sensor main body including a detection unit that detects external information; a sensor attachment bracket used to attach the sensor main body to a vehicle body frame member; and a sensor garnish including a window portion through which the detection unit is exposed in front view. The sensor garnish is provided on an outer side of the host vehicle so as to expose the detection unit of the external sensor and cover the sensor main body and the sensor attachment bracket excluding the detection unit. Small gaps are provided between the sensor main body and a window frame of the window portion in the sensor garnish. The window frame includes a noise suppression portion that suppresses wind noise due to airflow passing through the gaps along a rearward direction of the host vehicle.

A sensor mounting assembly for a vehicle includes a sensor that is operable to detect conditions outside of the vehicle, and a vehicle body structure having an inner wall and an outer wall located opposite the inner wall. A sensor mount is coupled to the outer wall with at least one fastener extending through the outer wall, inner wall, and sensor mount. The sensor mount defines an internal space in which the sensor is coupled.