An actuator includes a cylinder and a piston disposed in the cylinder. The piston has a head and a rod. The actuator further includes a collapsible locking member disposed in the head of the piston, and a gas-filled capsule disposed in the cylinder. The gas-filled capsule is in an expanded position when fluid in the cylinder is below a threshold pressure, and the gas-filled capsule is in a collapsed position when fluid in the cylinder is above the threshold pressure. The actuator also includes a lock piston operably connected to the gas-filled capsule. The lock piston engages the collapsible locking member and biases the collapsible locking member radially outward to a locked position when the gas-filled capsule is in the expanded position.

A disc for use in a pneumatic valve includes a stiffening insert encased in a flexible body. The stiffening insert acts to protect a central actuation region of the disc against radial compression, which may arise if the disc is used to seal against a bore hole, and against material flow towards the actuation region away from a clamped periphery. The behavior of the disc in a valve assembly is therefore more predictable and reproducible. The flexible body may further be tensioned across the stiffening insert.

The present disclosure relates to a piston-cylinder unit with a device for determining position, the device comprising at least one exciter that is indirectly or directly electrically connected with the cylinder jacket and the cylinder piston of the piston-cylinder unit, and that excites the electrical oscillating circuit formed by the piston-cylinder unit and the contact lines to oscillate at its resonant frequency, it being possible to measure an electrical signal characterizing the resonant frequency on the piston-cylinder unit. The invention also relates to a construction machine or piece of hoisting equipment with such a piston-cylinder unit.

A rodless power cylinder includes a cylinder body, a piston assembly adapted to reciprocate in the cylinder body, a magnet mounted at each of the two ends of the piston assembly, a valve mounted at each of the two ends of the cylinder body for guiding a flow of air or fluid in and out of the cylinder body to cause the piston assembly to reciprocate, a magnetic sensor mounted in a sensor mounting groove at each of the two valves for sensing the position of the respective magnet, a movable member mounted around the cylinder body and coupled to the piston assembly by a magnetic force for synchronous reciprocating motion.

A piston ring has a body member for sitting in a ring groove of a piston. The body member has an inner periphery, upper wall, lower wall and an outer periphery. The outer periphery has a concavity therein for storing lubricant therein. The upper wall has an outer section proximate to the outer periphery is constructed to be resiliently flexible between a flexed and unflexed position such during a portion of a power stroke, the volume of the concavity to store the lubricant is decreased by the flexing of the upper wall to the flexed position for expelling lubricant therefrom to a wall of the cylinder. The wall resiliently returns to the unflexed position during other times to allow excess lubricant from the wall of the cylinder to pass into the concavity.

A brake cylinder for pneumatic vehicle brakes, especially for commercial vehicles, includes in addition to a pneumatic locking mechanism, a manual release mechanism for manually releasing the spring brake section, and a device designed to visually recognize the manual release condition of the spring brake section outside of the housing.

A rotating cylinder includes a cylinder body, a piston, a piston shaft assembly, a main body and a guiding assembly. The cylinder body defines a receiving chamber. The piston, the piston shaft assembly, the main body and the guiding assembly are received in the receiving chamber. The piston shaft assembly is fixed to the piston, and defines at least one guiding groove lengthwise thereof. Each guiding groove includes a spiral portion and an extending portion. The main shaft is non-rotatably connected to the piston shaft assembly away from the piston and exposed out of the cylinder body. The guiding assembly sleeves on the piston shaft assembly and is slidably connected with the at least one guiding groove. The main shaft is driven to rotate when the guiding assembly engages the spiral portion, and move lengthwise when the guiding assembly is slidably connected with the extending portion.

Cam follower roller device, notably for an internal combustion engine fuel injection pump, comprising a tappet (12) and a roller (14) mounted to rotate on the tappet and intended to press against a cam. The tappet (12) comprises a roller support body (16), a shaft (26) for mounting the roller on the said body, and a guide sleeve (18) attached to the support body and at least partially surrounding the said body. The ends of the shaft are fixed in through-holes in the support body.

A device for actuating a flap, in particular a wastegate flap in an exhaust gas turbocharger for an internal combustion engine, includes a control rod, which can be moved by an actuator substantially in an axial direction and is guided in a fist gate via a first pin at the side thereof facing away from the actuator. A carriage is articulated on the first pin and is guided in the first gate via a second pin on the side facing away from the first pin, wherein a pivot lever is articulated on the second pin and, on the side facing away from the second pin, the pivot lever is rotatably mounted in a machine housing, preferably a turbine housing, and the flap is arranged on the pivot lever on the side facing away from the second pin. By way of the articulated design, a non-linear adjustment of the flap is possible.

A device for the pulsed release of an amount (3) of fluid that is stored in a storage housing (2) includes a piston (5) biased by a first spring (4) and movable within the storage housing (2) to dispense the fluid by the spring bias, when triggered by an actuator (6) to release a lock holding the piston in place (7). The lock (7) has individual catches (8) keeping the piston (5) in its pretensioned position and, when actuated by the actuator (6), releases the piston (5).

An end member for a gas spring assembly is dimensioned to receivingly engage an end of a flexible wall. The end member can be formed from polymeric material and can include a side wall receiving the end of the flexible wall. The end member can also include a base wall extending transverse to the side wall and dimensioned to abuttingly engage a jounce bumper of the gas spring assembly. The end member can include a mounting ridge or a mounting channel for engaging an associated structural component. A gas spring assembly including such an end member is also included.

A cylinder liner for insert casting which is excellent in heat conductivity with a cylinder block is provided, the cylinder liner for insert casting of the present invention comprising a cylinder liner for insert casting 2 which is formed with projections 5 with heights of 0.3 to 1.2 mm and undercut parts 6 in a ratio of 20 to 80/cm2 on an outer circumferential surface 4 over which, in turn, a thermally sprayed layer 7 is covered, wherein the thermally sprayed layer 7 is comprised of a ferrous material and wherein a ratio of a surface area of a thermally sprayed layer 7 surface at a certain region on the outer circumferential surface 4 of the liner with an area of the region is 12 to 23. The thermally sprayed layer preferably has a thickness of 0.01 to 0.2 mm. The thermally sprayed layer is preferably formed using a wire shaped thermal spraying material.

Provided is a vehicle front structure including a front bumper and a lower grille. The front bumper includes a front-bumper lower surface extending in a vehicle rear direction, the front-bumper lower surface having a pair of bottom surface portions at respective side portions and a recessed surface at a center portion, the recessed surface extending from the pair of bottom surface portions and being recessed in an upper direction. The lower grille includes an annular portion arranged at the lower side of a rear end of the recessed surface and forming an opening, a protruding portion protruding from a lower portion of the annular portion so as to protrude in a front direction and oppose to the recessed surface, and a reinforcing portion extending from an upper portion of the annular portion to a back surface of the recessed surface and reinforcing the front-bumper lower surface.

There is provided a vehicle body structure that can improve collision performance at the time of a rear collision. The vehicle body structure includes first and second crash boxes that are provided at rear ends of rear side members. Further, the second crash boxes are disposed at positions different from the positions of the first crash boxes in a vertical direction of the vehicle. The second crash boxes, which are disposed at the positions different from the positions of the first crash boxes, can absorb a load applied from bumper reinforcement of another vehicle. Since a load at the time of a rear collision is absorbed by the second crash boxes, it is possible to suppress the deformation of a trunk that is provided at the rear portion of a vehicle body.

Disclosed herein is a drying apparatus for a vehicle using vehicle induced wind. The drying apparatus is capable of drying a wet object using vehicle induced wind generated by the driving of the vehicle. The apparatus includes a storage cover that is rotatably coupled to a rear bumper cover via a hinge module, to form a storage space between the storage cover and the rear bumper cover. In addition the apparatus includes an inlet cover that is coupled to the rear bumper cover to form an inlet passage through which the vehicle induced wind flows into the storage space when the vehicle is being driven. A plurality of outlet holes are formed in the rear bumper cover, and are configured to operate as a passage to allow air to be discharged from the storage space to an exterior of the vehicle.

A bumper assembly includes a bumper beam having a bumper beam surface extending along a bumper plane X and a crash box including a crash box surface extending along a crash box plane Y. One of the bumper beam and the crash box includes an alignment joint to mate the bumper beam and the crash box and dispose the surfaces in abutting and aligned relationship relative to one another for establishing a linear load path extending linearly along the planes X, Y. A method of assembling a bumper assembly includes the steps of mating the bumper beam and the crash box about the alignment joint and connecting the bumper beam and the crash box together along the alignment joint. The step of connecting the bumper beam and the crash box includes friction stir welding the bumper box and the crash box together along the alignment joint.

A structure for absorbing frontal collision energy of a vehicle absorbs frontal collision energy of a vehicle using both front side members configured to support a bumper beam disposed at a front side of a vehicle body, a shock absorber housing panel disposed outside the front side member, and a fender apron member disposed outside the shock absorber housing panel, and the structure includes: an enlarged member installed to be inclined between an outer surface of the front side member and a rear surface of the fender apron member so as to be spaced forward and apart from the outer surface of the front side member; and an enlarged frame engaged between a lower side of the fender apron member and a front mounting portion of a sub-frame.

An adjustable air diffuser is disposed in an airflow channel into which a travelling wind is directed through an opening provided in a bumper face. The diffuser opens and closes the channel by movable louver blades driven by an actuator. An upper part of the diffuser is disposed to face a rear wall of the bumper face and is attached to a bumper beam extending along a vehicle width direction. A lower part of the diffuser is attached to a vehicle body structural member. The attachment structure includes a column that is disposed behind the adjustable air diffuser. A lower end of the column is attached to a lower end of the adjustable air diffuser. Weak portions are provided on the column such that the column breaks when the column interferes with another member behind the column.

A pedestrian-friendly forward structure of a motor vehicle includes a grill opening reinforcement (GOR), a front fascia located forward of and spaced from the GOR, and a support bracket extending transversely to the vehicle forward of the GOR and rearward of the front fascia. The support bracket has a transverse cross-bar and left and right legs extending rearward from a cross-bar adjacent opposite ends thereof. The legs are attached to respective outboard positions on the GOR, and the cross-bar has an upper flange underlying an upper rear panel of the front fascia. If a pedestrian strikes the forward structure, the fascia and support bracket yield rearward in an injury-reducing manner.

A grill opening reinforcement (GOR) assembly of a vehicle is provided. The GOR assembly includes a shutter body formed to define a first opening, a front fascia and a seal. The shutter body includes a top portion, first and second side support members and a bottom portion. The front fascia is formed to define a second opening and is supportively attachable to the shutter body. The seal is disposable on a leading edge of at least one of the first and second side support members and the bottom portion and is configured to define an airflow path from the second opening to the first opening.

A vehicle bumper for use with police and other emergency vehicles for pushing another vehicle which is fabricated of a tubular loop defining a generally oval cross-section. The oval cross-section tubular loop is oriented such that the major axis of the oval cross-section extends front to back with respect to the host vehicle while the minor axis extends up and down. The vehicle bumper further supports a plurality of resilient pads to aid in controlling the pushed vehicle and to cushion impact transfer between the bumper and the pushed vehicle. The inventive vehicle bumper is substantially stronger and substantially lighter in weight while simultaneously providing a more attractive front view cross-section when mounted on a host vehicle. A plurality of attachments are secured to the tubular loop and are used in securing the vehicle bumper to a suitable portion of a host vehicle.

A bumper absorber (9) has a squared U-shaped cross section formed of: a vertical face (11) extending in a top-bottom direction and a vehicle width direction, and a top face (12) and a bottom face (13) respectively extending rearward from a top end and a bottom end of the vertical face (11). The bumper absorber (9) is configured such that the top face (12) and the bottom face (13) thereof are supported by the bumper reinforcement (10) via multiple attachment members (23 to 27), and an interval between the attachment members adjacent to each other in the vehicle width direction is set to decrease from end portions (9b) in the vehicle width direction toward a central portion (9a) in the vehicle width direction.

A collision energy absorption apparatus and a vehicle front end structure including the apparatus. The apparatus is welded to a bumper beam and is laterally adjacent a longitudinally extending member disposed behind the bumper beam. The apparatus has a central body having a front edge attached to the bumper beam and a rear edge that is spaced from the bumper beam and the longitudinally extending member. Upper and lower triangular walls extend between the central body and the longitudinally extending member. A rib extends laterally outwardly from the central body.

A robot bumper assembly includes a bumper body, a first sensor array, and a second sensor array. The first sensor array is disposed along and contoured to the periphery of a forward facing portion of the bumper body and senses contact with an external environment at positions along the contour of the periphery forward facing portion of the bumper body. The second sensor array is disposed along and contoured to the periphery of a top portion of the forward facing portion of the robot body. The top portion is angled, ramping up. The second sensor array senses contact with an external environment at positions along the periphery of the angled top portion of the bumper body.

The device may have a plurality of upright supports where the supports may include a mounting plate with mounting openings, a plurality of vertical members that may be in non-welded communication with the extruded back mounting plate and a plurality of horizontal members where the vertical members provide strength and support to the supports. The horizontal under-run prevention beam may include mounting openings that correspond to the horizontal beam mounting openings and a removable reflective strip that correspond to reflective strip openings in the beam. The vertical and horizontal members may be stacked extruded rectangles of the desired widths and lengths.

The invention relates to a vehicle bumper assembly (1) having a bumper cross-member (2) and at least two energy-absorption components (3), which are arranged at a distance from one another and which are connected to the rear side of the bumper cross-member (2) and supported thereon by means of a first end. The energy-absorption components have an x-direction absorption effective direction oriented perpendicular to the y-axes longitudinal extension of the bumper. The energy-absorption components (3) are designed to be supported on a chassis part (4) of a vehicle by means of the end of the energy-absorption components pointing away from the bumper cross-member, wherein the energy-absorption component (3) has a slanted end face (5) in the direction toward the bumper cross-member (2). According to the invention, the entire or substantially the entire end face (5) of the energy-absorption component (3) is supported on the rear side of the bumper cross-member (2), and the plane of the end face (5) of the energy-absorption component (3) facing the bumper, and thus the bumper cross-member (2), is oriented such that the front side thereof is arranged at an angle to the plane extending orthogonally to the force application direction of the AZT structure test.

A deployable pedestrian protection lower leg stiffen apparatus includes a left and a right linear actuator mountable adjacent to respective left and right forward frame members of a vehicle and a lower leg stiffener attached to and movable by the actuators. The actuators are extendable along respective deployment axes extending forward and downward relative to the vehicle to move the stiffener between a retracted position rearward of a forward surface of a front bumper beam and above a ground clearance plane and a deployed position forward of the retracted position and below the ground clearance plane. The actuators have rotational joints defining a horizontal pivot axis about which at least the forward portions of the piston may rotate upward along with the stiffener to prevent damage to the system if it strikes a road obstacle.

The assembly is for mounting to a motor vehicle having a bumper skin and it comprises a body part forming at least a portion of a bumper skin. The body part is defined by bottom and top edges. The top edge includes a first portion to be masked by a member of the vehicle that is to be fitted to the body part. The assembly includes at least a first masking element masking at least one portion of the bottom edge and at least a second masking element masking at least one second portion of the top edge of the body part, complementary to the at least one first portion of the top edge of the body part. The first and second masking elements are fixed relative to the body part once the assembly is mounted to the motor vehicle.

A vehicular crash sensing system includes a bumper cap for contacting a bumper. A chamber fits into a side rail attached to the bumper, the chamber being sealed by the bumper cap. A stop element limits movement of the chamber into the side rail. A pressure sensor detects an increased chamber air pressure during crushing of the chamber resulting from movement of the bumper with respect to the stop element.

A motor vehicle includes a first side member having first lower and upper darts. The motor vehicle also includes a second side member parallel with and spaced apart from the first side member, the second side member having second lower and upper darts. The upper darts are positioned between the lower darts and end portions of the respective first or second side members. The motor vehicle further includes first and second bumper brackets coupled to the end portion of the respective first or second side members, a bumper reinforcement member coupled to the first and second bumper brackets, and a counter rotation bracket coupled to the bumper reinforcement member and extending upwards from the bumper reinforcement member. The lower darts and the upper darts form a preferential buckling zone of the first and the second side members.

A fascia support structure and aerodynamic shutter assembly for a vehicle includes a fascia support structure, comprising: a top portion comprising a substantially U-shaped body comprising a top fascia support member, a first side fascia support member and a second side fascia support member, the first side fascia support member having a first side baffle, the second side fascia support member having a second side baffle; and a bottom portion comprising a bottom baffle, the bottom portion attached to the first and second side fascia support members, the top portion and the bottom portion comprising a fascia support structure opening, at least one of the first side baffle, second side baffle or bottom baffle having a seal member disposed on a leading edge. The assembly also includes an aerodynamic shutter system comprising a shutter frame having a shutter frame opening and a plurality of rotatable shutters disposed therein.

A vehicle bumper system comprises a bumper reinforcement beam and an energy absorber with top and bottom rows of similarly-shaped spaced-apart crush lobes in alternating relation for uniform impact resistance across the bumper system. The illustrated top row of crush lobes provides a high first force-deflection curve for high impact forces, and the bottom row of crush lobes provides a lower second force-deflection curve, for pedestrian reduced injury. An elongated sensor is positioned under shear walls of the top and bottom crush lobes, and is retained by tabs on the energy absorber. This positively retains the sensor in position on the bumper system, with few (or zero) separate fasteners, while facilitating quick assembly and reliable operation of the sensor tube.

A vehicle bumper beam including: a resin beam having an elongate body extending along a vehicle-width direction, two tubular shock-absorbing portions disposed at the beam body's opposite longitudinal end portions extending in front-rear direction, the beam body and shock-absorbing portions being formed with each other; a metal beam disposed outside the resin beam in the front-rear direction, fixedly fitted to the resin beam. Further, flat attachment portions, formed with inner end portions of the shock-absorbing portions in front-rear direction; bent portions bent in a crank extending from attachment portions outward in front-rear direction, the beam body being to attachment portions via bent portions, the metal beam fixedly fitted to an outer surface of the beam body's intermediate portion; metal beam's opposite end portions extending beyond bent portions covering the right and left sides, fixedly fitted to distal end portions; each space defined by shock-absorbing portion, metal beam and bent portion.

A countermeasure assembly for an automotive vehicle includes a front side rail extending in a generally longitudinal direction; a bumper having a main bumper member and a bumper extension forming an end portion of the bumper; and a pivot link having front and rear mounting portions. The front mounting portion is pivotably engaged with the bumper extension member to define a front pivot joint, and the rear mounting portion is pivotably engaged with the front side rail to define a rear pivot joint. The rear pivot joint is located rearward and inward from the front pivot joint. The bumper extension is bolted to the forward end of the front side rail. The bumper extension has a front member and a rear member, of which the rear member is bolted to the front side rail. The front member and the rear member of the bumper extension define a hollow box structure.

A body on frame vehicle includes a vehicle frame having a small offset impact load management system including upper and lower rear blocker structures and a reinforcement blocker structure for managing impact loads applied to the wheel and tire of the vehicle from being directed further toward the body. The reinforcement blocker structure includes a base member welded to openings in the frame side rail and extending angularly outwardly and located rearward and distal the wheel and tire and proximal a longitudinal cross frame member for transferring the small offset impact loads transferred by the wheel and tire in a cross vehicle direction.

A material handling vehicle includes a laminated bumper that provides both durability and reduced energy transmissibility. The laminated bumper includes at least a first bumper layer and a second bumper layer, such that at least one of the first bumper layer and second bumper layer of the laminate bumper are allowed to translate upon bumper contact with an object.

A bumper (10) created using a resistive implant welding process. The bumper includes a mounting plate portion (12) and a composite bumper portion (14). The mounting plate portion (12) is connected to the composite bumper portion (14) using a resistive implant welding process. In one embodiment, the present invention includes a bumper for a vehicle having a mounting plate (12) and a bumper portion (14). The bumper portion (14) includes at least one flange (24) formed as part of the bumper portion (14), a first contact area (28) formed as part of the mounting plate (12), and a second contact area (30) formed as part of the flange (24). A connection point is used to bond the first contact area (28) and the second contact area (30) such that the mounting plate (12) is connected to the bumper portion (14).

A panel member having a U-shaped cross section includes step portions at an upper face portion and a lower face portion, and a distance, in a vehicle longitudinal direction, of the step potions from a panel member formed substantially in a flat-plate shape, is configured such that the distance at a central portion, in the vehicle width direction, of a bumper reinforcement is the maximum and the distance decreases gradually toward an outward direction of the vehicle. Accordingly, the vehicle-body structure which can properly ensure the bending strength and also attain the light weight of the bumper reinforcement, improving the load transmission from the bumper reinforcement to crash cans, can be provided.

A system for protecting a pedestrian during impact with a vehicle, the system having a bumper adapted for attachment to an end of the vehicle, wherein the bumper is comprised of a plurality of air sacs, wherein the bumper has a horizontal thickness extends from the end of the vehicle, wherein at least some of the plurality of air sacs stretch and then burst during impact between the bumper and a pedestrian causing deceleration along the horizontal width of the bumper during the impact, wherein the bumper undergoes plastic deformation during impact with the pedestrian as the at least some of the air sacs burst during impact, and wherein the bursting of some of the plurality of air sacs reduces spring back of the bumper on the pedestrian.

A front bumper assembly including a bumper beam and two deflectors are provided on right and left sides of the front bumper assembly. The deflectors include hook-shaped portions and telescopic portions. The telescopic portions are received within the front bumper assembly. The hook-shaped portion of the deflector may be engaged by a rigid barrier aligned with the deflectors. In the event of a collision, the rigid barrier engages one of the hook-shaped portions and withdraws the telescopic portion from the front bumper assembly. The deflector is pulsed outwardly to move the front wheel and tire assembly to a tow-in orientation.

Disclosed is an external airbag apparatus. The apparatus includes, a back beam disposed on one surface directed toward a bumper on which an airbag module is disposed. The apparatus additionally includes a deployment guide disposed between the bumper and the back beam, both ends of which are coupled to the back beam, and a middle end of which is supported on the bumper. Furthermore, the apparatus includes a sensor disposed between the deployment guide and the back beam to sense impact when pressed by the deployment guide during impact to the bumper.

A front-end assembly including a deflector and a catcher bracket. The V-shaped deflector is attached to a bumper of a vehicle, a rear leg of the deflector has a distal end disposed adjacent to the frame rail. In a collision, the distal end of the rear leg engages the catcher bracket to reduce intrusion into the passenger compartment of the vehicle.

The vehicle attachable carrier device includes a mounting bracket assembly for movably mounting a guard frame to a vehicle that includes a bracket coupled to the vehicle. A frame is movably coupled to the bracket. The frame may guard the vehicle. The frame is positionable between a stored position and an extended position.

An airflow control device is mounted to the front end of an automotive vehicle and includes an upper air scoop section having a scoop channel disposed rearward of a bumper assembly and oriented to direct airflow entering a bumper intake opening toward an air-receiving powertrain component. A lower air dam section extends downwardly from the upper section to be positioned below a lower extent of the bumper assembly to deflect airflow away from an underside of the vehicle.

An airbag system mitigates intrusion in the event of an offset rigid barrier impact to a forward corner of a motor vehicle. An airbag is attached proximate a distal end of a front rail. When in the inflated condition, the airbag has an angular leading edge. An impact detection sensor generates a signal upon a corner impact event, whereby a controller processes the signal generated by the detection sensor and electrically actuates an inflator upon a predetermined impact severity. The angular leading edge of the airbag in the inflated condition acts against the offset rigid barrier to generate a lateral force against the offset rigid barrier to push the motor vehicle away from the barrier and thereby redirect impact energy by lateral movement of the motor vehicle.

A robot bumper including a bumper body having a forward surface and a top surface angling away from the forward surface. The bumper body conforms to a shape of a received robot chassis. The robot bumper also includes a force absorbing layer disposed on the bumper body, a membrane switch layer comprising a plurality of electrical contacts arranged along the top surface of the bumper body, and a force transmission layer disposed between the force absorbing layer and the membrane switch layer. The force transmission layer includes a plurality of force transmitting elements configured to transmit force to the membrane switch layer.

A safety guard for a vehicle, such as a school or transit bus, tractor trailer or the like-type vehicle, includes a front guard positioned at an angle in front of a wheel of the vehicle that will function to push individuals and other animate objects lying in the path of the vehicle out of the path of the wheels for safety purposes, while being mounted for telescoping movement to protect the safety guard from damage upon abutting an inanimate object during operation of the vehicle.

When a collision load is transmitted to a gusset, the load is transmitted to an inner side in a vehicle width direction via an inclined wall. Accordingly, moment that causes a front side member to be projected and bent inward to the inner side in the vehicle width direction with an intersection being a starting point acts on the front side member. Then, the front side member, which has been projected and bent inward, collides with a power unit that is disposed in an engine compartment from an outer side in the vehicle width direction. Accordingly, a lateral force to the inner side in the vehicle width direction can be obtained for a vehicle.

A tool bar for securing under a hood of a car during repair and maintenance is disclosed. A rigid member spanning a substantial portion of the hood is flexibly secured to hooks. The hooks engage edges of the hood and may include a compliant covering. The hooks may secure to the rigid member by means of straps and the straps may be tensioned by means of tensioners secured to one of the hooks and the rigid member. A stabilizer secures to the rigid member and has an end that may be clipped or otherwise fastened to a portion of the hood to resist rotation of the rigid member. One or more tool retaining members secured to the rigid member, such as a socket rack, magnetic bar, hook groove, or the like.

Vehicle structures for dissipating energy associated with a collision are described herein. In one embodiment, a vehicle includes a side support extending in a vehicle longitudinal direction, a bumper assembly coupled to the side support and extending in a vehicle lateral direction that is transverse to the vehicle longitudinal direction, and a repositionable joint assembly extending between and pivotally coupled to the side support and the bumper assembly, the repositionable joint assembly including an outboard linking member pivotally coupled to the bumper assembly at a bumper securement location, an inboard linking member pivotally coupled to the side support at a side support securement location, and a fulcrum portion, where the outboard linking member is pivotally coupled to the inboard linking member at the fulcrum portion.