Car body with a shear element on one side

A car body, for example, a front or rear frame is provided. The car body includes at least one crossmember and at least one pair of left and right braces that are arranged at least substantially symmetric to the crossmember. The car body also includes a shear element that is designed for absorbing shear forces during a collision and that is mounted on a brace of the pair, wherein no shear element is provided symmetrically thereto on the other brace of this pair.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to German Patent Application No. 10 2011 115 587.6, filed Oct. 11, 2011, which is incorporated herein by reference in its entirety.

TECHNICAL FIELD

The technical field pertains to a car body with a shear element on one side.

BACKGROUND

A front frame of a motor vehicle with a crossmember and a pair of left and right longitudinal braces that are arranged symmetric relative to the crossmember is known, for example, from DE 10 2005 043 707 A1. Nowadays, car bodies generally are at least partially symmetric along the plane of the longitudinal and the vertical vehicle axis.

In certain instances, such as during a collision with lateral components such as, e.g., the 10° load scenario according to the RCAR test protocol, in which a corner of the motor vehicle collides with a barrier that is inclined relative to the lateral vehicle axis by 10°, the forces introduced into the car body on one side in the collision area can lead to an asymmetric load distribution and consequently to a lateral displacement of car body elements, such as, the crossmembers.

In this context,FIG. 1schematically shows a conventional car body with several crossmembers1.1to1.5-L and several pairs of left (index “-L”) and right (index “-R”) braces2.1to2.3, andFIG. 2shows the car body after a collision with a barrier that is inclined relative to the lateral vehicle axis by 10°. The lateral loads and lateral displacements in the crossmembers are indicated with arrows and result in an expansion of the assemblage, particularly the asymmetric deformation of the car body.

Accordingly, it can be desirable to provide an improved car body. In addition, other objects, desirable features and characteristics will become apparent from the subsequent summary and detailed description, and the appended claims, taken in conjunction with the accompanying drawings and this background.

SUMMARY

According to one practice, shear plates are mounted on crossmembers and braces, wherein these shear plates absorb forces and reduce or prevent a lateral displacement and/or assemblage expansion. Since it cannot be predicted on which side of the vehicle a collision occurs and corresponding forces are introduced, shear plates of this type are symmetrically distributed such that, in pairs of left and right braces, the left as well as the right brace is respectively connected to the crossmember by means of a shear plate. However, this reduces the available structural space in the area of the car body, particularly when using plate-like shear elements. For example, if shear plates20′ are respectively arranged symmetrical or on both sides of the front frame according toFIG. 1as indicated with broken lines inFIG. 1, the structural space in the front section of the car is restricted and therefore can no longer be used for accommodating a water reservoir, a horn, electronic components or the like.

According to one of various aspects of the present disclosure, provided is a one-sided shear element that is mounted on only one brace of a pair of left and right braces, which can significantly reduce the lateral displacement and assemblage expansion. Consequently, structural space for accommodating vehicle components such as water reservoirs, a horn or the like remains on the opposite side, on which no symmetrical shear element is provided.

According to another exemplary aspect of the present disclosure, a car body, for example, a front frame or rear frame, features one or more central crossmembers relative to, for example, the plane of the longitudinal and the vertical vehicle axis, as well as one or more pairs of left and right braces that are arranged at least substantially symmetric to such a crossmember. According to one of various exemplary embodiments, the braces may extend at least substantially in the longitudinal, the vertical and/or the lateral direction of the vehicle. In the context of the present disclosure, the crossmembers extend at least substantially in the lateral direction of the vehicle in one example, but may also be inclined relative to the lateral direction of the vehicle.

According to this exemplary aspect of the present disclosure, one or more shear elements are provided in order to absorb shear forces during a collision. In this case, one or more shear elements are arranged between the one brace of a pair of left and right braces and a crossmember and mounted on the brace and another car body element, for example, the crossmember, wherein no shear element is provided symmetrically thereto between the crossmember and the other brace of this pair.

In this way, structural space for vehicle components is cleared on the side of the other brace such that, according to one exemplary enhancement, one or more vehicle components such as water reservoirs, a horn or the like can be accommodated in the space between the other brace of a pair of left and right braces and the crossmember symmetric to the shear element that is mounted on the one brace of the pair. As mentioned above, the lateral displacement and the assemblage expansion can also be significantly reduced with this one-sided shear element.

One or more shear elements may be respectively arranged between a crossmember and a brace of a first pair of left and right braces that are arranged at least substantially symmetric to the crossmember and between the same or another crossmember and a brace of a second pair of left and right braces that are arranged at least substantially symmetric to this crossmember, wherein no shear element is provided symmetrically thereto between the respective crossmember and the respective other brace of the first and second pair. The one-sided shear elements of the first and second pair may be arranged on the same side of the vehicle or on opposite sides of the vehicle. Two or more shear elements may be additionally or alternatively arranged between a crossmember and one brace of a pair of left and right braces that are arranged at least substantially symmetric to this crossmember, wherein no shear element is provided symmetrical to one or more of these shear elements between the crossmember and the other brace of this pair. It would therefore be possible, for example, to provide one side of the vehicle with two shear elements while the other side of the vehicle is provided with only one shear element or no shear element at all. According to one exemplary embodiment, one or more shear elements are mounted on one brace of a pair of left and right braces and no shear element is provided between the crossmember and the other brace of this pair.

A shear element may be arranged on the left or the right side of the vehicle. It may extend in the longitudinal, the vertical and/or the lateral direction of the vehicle between the crossmember and one brace of the pair. According to one of various exemplary embodiments, it extends in the longitudinal, the vertical and the lateral direction of the vehicle and therefore is inclined relative to the longitudinal, the lateral and the vertical vehicle axis, i.e., it extends diagonal to a generally frame-like car body.

According to one exemplary embodiment, a shear element is realized in a rod-like or plate-like fashion. In comparison with a plate-like shear element or a frame-like or solid shear element, a rod-like shear element or a shear rod occupies less structural space, is able to adequately absorb and transmit forces in the (longitudinal) direction of rod and also has a lower weight. However, a plate-like shear element may have the advantage of being able to better absorb and transmit lateral forces and moments.

According to another exemplary embodiment, the shear element features a tubular center part, wherein a flattening for respectively mounting the shear element on the crossmember and one brace of the pair is realized on one or both end faces of the center part. Such a shear element can be easily manufactured and mounted and has a low weight. A bore may be arranged in a flattening in order to screw down the shear element.

According to another exemplary embodiment, the shear element is permanently mounted on the crossmember and/or one brace of the pair. It may be mounted, for example, by means of welding, soldering, bonding, riveting and/or caulking. This advantageously makes it possible to produce a permanent connection that is less sensitive to vibrations. A shear element may likewise be separably mounted on the crossmember and/or one brace of the pair. In this case, it may be mounted, for example, by means of screws. This simplifies the mounting of the shear element, as well as its replacement, e.g., in case of a defect.

According to another exemplary embodiment, the shear element is rigidly mounted on the crossmember and/or one brace of the pair in order to enable the shear element to also transmit moments. It may likewise be mounted on the crossmember and/or one brace of the pair in an articulated fashion in order to compensate, for example, distortions of the car body.

According to another exemplary embodiment, the crossmember and/or the one brace feature a holding bracket for mounting the shear element. This makes it possible to compensate for an offset between, for example, the orientation of the mounting surfaces on the crossmember and on the brace.

A shear element therefore may be directly or indirectly mounted on a brace and/or a crossmember. It would be possible, for example, to arrange at least one additional brace that extends in the longitudinal, vertical and/or lateral direction of the vehicle between a crossmember and a shear element such that the shear element is indirectly mounted on the crossmember by means of this (these) additional brace(s). In the context of the present disclosure, an arrangement of a shear element between a brace and a crossmember generally refers, for example, to an arrangement in the force flow such that the shear element transmits tensile, compressive and/or lateral forces and/or bending moments and/or torsional moments between the crossmember and the brace. In the context of the present disclosure, an arrangement of a shear element between a brace and a crossmember likewise refers, for example, to the shear element spatially bordering on the brace and the crossmember, wherein at least one additional brace may also be intermediately arranged between the crossmember and the shear element as described above. In the context of the present disclosure, an arrangement between a brace and a crossmember furthermore refers, for example, to an arrangement in a space that is at least partially defined by the brace and the crossmember.

A person skilled in the art can gather other characteristics and advantages of the disclosure from the following description of exemplary embodiments that refers to the attached drawings, wherein the described exemplary embodiments should not be interpreted in a restrictive sense.

DETAILED DESCRIPTION

As initially mentioned,FIG. 1shows a conventional car body with three central crossmembers1.1to1.3and two pairs of left and right crossmembers1.4-L,1.4-R and1.5-L,1.5-R. The car body furthermore features three pairs of left and right braces2.1-L and2.1-R,2.2-L and2.2-R, as well as2.3-L and2.3-R. These braces may respectively extend in the longitudinal and/or vertical direction of the vehicle such thatFIG. 1may represent a front view in the longitudinal direction of the vehicle or a top view in the vertical direction of the vehicle. Accordingly, the reference symbol “A” identifies a longitudinal or vertical vehicle axis that is illustrated in the form of a dot-dash line. In this context, it should be emphasized that the schematically indicated braces may also extend in the lateral direction of the vehicle that is indicated in the form of a dot-dot-dash line inFIG. 1and identified by the reference symbol “Q.” The pairs of left and right crossmembers1.4-L,1.4-R and1.5-L,1.5-R, for example, accordingly could also be interpreted as pairs of left and right braces in the context of the present disclosure.

As initially mentioned,FIG. 2shows the car body according toFIG. 1during a 10° load scenario. The arrows indicate lateral displacements of car body elements in the lateral direction of the vehicle Q and the expansion of the assemblage. The structural space for other vehicle components would be significantly restricted if plate-like shear elements20′ would be arranged on both sides as indicated inFIG. 1.

In the car body according to an exemplary embodiment of the present disclosure that is illustrated inFIG. 3, a shear rod10consequently is arranged on one side between the right crossmember1.4-R and the right brace2.1-R or the crossmember1.1, respectively, while no shear rod is provided symmetrically thereto, i.e., in the lower right corner ofFIG. 3. In this way, structural space for accommodating a water reservoir, horn and/or other vehicle components, collectively and/or individually schematically represented by structure30inFIG. 3, is made available at this location while the one-sided shear rod10simultaneously reduces a lateral displacement and assemblage expansion during an offset collision such as, e.g., the 10° load scenario according to RCAR. In other respects, the design corresponds to the embodiment according toFIG. 1, wherein corresponding elements are identified by identical reference symbols such that only the differences between these embodiments are discussed. The frame inFIG. 3may be a front frame or a rear frame, depending on perspective, with crossmember1.4being interior to crossmember1.1.

FIG. 4shows a car body according to another exemplary embodiment of the present disclosure in the form of an illustration that corresponds to that inFIG. 3, wherein corresponding elements are once again identified by identical reference symbols such that only the differences between these exemplary embodiments are discussed.

In the exemplary embodiment according toFIG. 4, a one-sided shear element20realized in a plate-like fashion is arranged on the other, left side of the vehicle (on the right inFIG. 4). This shear element can absorb moments in a superior fashion. On the other side, a shear element with a rod-like design, e.g., of the type used in the exemplary embodiment according toFIG. 3may make it possible to also accommodate (not-shown) smaller vehicle components, for example, electronic components, at this location.

FIG. 5shows part of the car body according toFIG. 3in the form of a perspective view. This figure shows the shear rod10that extends in the longitudinal, lateral and vertical direction of the vehicle, i.e., diagonally. It features a tubular center part, both sides of which transform into a flattening with a through-bore arranged therein. Screws11that are respectively screwed to the brace and the crossmember directly or by means of a holding bracket12extend through these through-bores. The holding bracket12compensates the offset between the orientations of the two car body mounting surfaces for the shear rod10and is generally welded or bonded to the car body.