EP2539184A1

EP2539184A1 - Crashbox for a motor vehicle

Info

Publication number: EP2539184A1
Application number: EP11703665A
Authority: EP
Inventors: Thomas Friedrich; Sven Robert Raisch
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2010-02-26
Filing date: 2011-02-11
Publication date: 2013-01-02
Also published as: US20130048455A1; DE102010018316A1; WO2011104130A1; CN102770309A

Abstract

The invention relates to a crashbox (10) for a motor vehicle (12) having at least one crashbox component (14) which can be deformed in the event of a crash and which, in the event of a crash, absorbs energy as a result of deformation. According to the invention, the crashbox (10) comprises at least one weakening tool (16) which, in order to adjust the energy absorption capability of the crashbox component (14) weakens the entire structure of the at least one crashbox component (14), as a result of which the rigidity of the crashbox component (14) can be reduced.

Description

description

title

Crashbox for a motor vehicle prior art

The invention relates to a crash box for a motor vehicle according to the preamble of independent claim 1. From EP 1 792 786 A2 a generic crash box for a motor vehicle is known. Here, a crash box for integration between a bumper cross member and a vehicle longitudinal member of the motor vehicle is provided, which has a housing-like deformation profile as a folded construction made of sheet metal and a longitudinal carrier side flange plate, wherein the flange is formed as part of the folding construction. The crashbox takes in the

Crash due to the deformation of the deformation profile energy, the energy absorption capacity of the crash box is not adjustable here.

From DE 10 2006 058 604 A1 a crash box for a motor vehicle is known. The crash box comprises two crash box parts, which are movable relative to one another in the event of a crash and which are arranged between two support plates. A first crash box part is designed as a deformation profile arranged between two support plates, which is surrounded by the second crash box part designed as a jacket. In the event of a crash, the jacket is everted outwards in the region of a support plate, so that a part of the crash energy is absorbed by the outer-side everting. In addition, deformation work is performed in the area of the deformation profile by shortening the deformation profile wrinkling.

From DE 100 14 469 A1 a crash box in the form of an impact damper is known, which is arranged between a longitudinal member and a cross member in a bumper of a motor vehicle. The crash box has a hollow body configured deformation profile with a transverse to a longitudinal axis extending bead, the deformation profile is composed of two half-shells. From DE 20 2007 006 376 111 an energy absorbing device for vehicles is known which comprises a vehicle part and a chipping device, wherein for absorbing the energy, the vehicle part can be machined by means of the chipping device. Disclosure of the invention

The crash box according to the invention with the features of independent claim 1 has the advantage that the crash box comprises at least one weakening tool that weakens the overall structure of the at least one crash box part for adjusting the energy absorption capability of the crash box part, whereby the rigidity of the crash box part is reduced. By making the stiffness of the crash box adaptive, the stiffness is adaptable before or during the crash, so that the energy absorption capability of the front structure of the vehicle is advantageously adjustable. As a result, an adaptation of the crash box to crashes with different objects is possible in an advantageous manner. If, for example, a pedestrian is recognized as an object, then the weakening tool can make a greater weakening of the overall structure of the crash box part than in the case of a crash with a second vehicle. Another advantage is the high degree of adaptivity that such a system possesses, since the principle can be applied to different crash box shapes. The energy-absorption characteristic of the crash box is selectively changeable during a frontal crash and can be adjusted according to the type of crash, for example, in a collision against a light vehicle or a pedestrian, the crash box is set to "soft" under the keyword partner protection and, for example, in a collision against a heavy vehicle the

Both properties, both the partner protection and the self-protection are combined in an advantageous manner in crash compatibility.This combination signifies in a particularly advantageous manner, a high degree of self-protection with low aggressiveness compared to other road users, said An improvement in compatibility is not at the expense of the self-protection of the vehicle. Advantageously, in the crash box according to the invention energy is absorbed by two physical principles of action, namely on the one hand by cutting work and on the other hand by plastic deformation. This allows a higher level of absorbed energy with low space requirement or large construction of the crash box while saving weight. Of course, the adaptability of the crash box can only be realized by the cutting work.

Advantageous improvements of the crash box specified in the independent claim 1 are possible due to the measures and developments listed in the dependent claims.

It is particularly advantageous that an evaluation and / or control unit in the motor vehicle for the adaptive adjustment of the energy absorption capacity of the crash box part evaluates data of a sensor system which includes information about the vehicle environment and / or crash severity. The main advantage lies in an arbitrarily adjustable and variable energy absorption capacity of the crash box part. The weakening of the overall structure of the crash box part can be selectively adjusted depending on a detected object, the collision speed of the motor vehicle relative to the object and / or the crash type. Advantageously, a variable adaptation of the energy absorption by the crash box of a vehicle and thus an optimal influencing of the speed reduction of the motor vehicle for better protection of the occupants and the crash partners is thereby possible. By means of this principle, it is possible to have a fully variable and ideally stepless adjustment of the energy absorption capacity of the

Crashboxteiles or Crashbox to allow and adjust this particular while driving collision, occupant, interior and / or Fahrsituationsab- pendent. In an embodiment of the invention, a sensor unit arranged in the region of the crash box part determines the speed at which the crash box part deforms in the event of a crash, and transmits this information to the evaluation and / or control unit, which preferably transmits the at least one weakening tool as a function of the determined speed activates an actuator unit. Here, the energy absorption capacity of the crash box part is set specifically. It is a quick and accurate adjustment of the weakening makes it possible, whereby the stiffness of the crash box part is specifically adjustable. This advantageously results in an optimal individual adaptation of the crash box to the conditions during a crash that actually occurs. In a further embodiment of the invention, the at least one weakening tool is arranged outside the crash box part and acts on an outer wall of the crash box part and / or arranged in a cavity of the crash box part and acts outwardly on an inner wall of the crash box part. This advantageously results in a variable adjustment of the energy absorption capability of the crash box component or a variable weakening of the overall structure of the crash box component

Crashboxteiles provided by a targeted destruction of the outer wall and / or the inner wall of the crash box part takes place. An essential advantage of this embodiment is a predictive force characteristic that can be impressed into the crash box part. This means that, depending on the crash severity, a more or less deep penetration of the weakening tool into the crash box part can take place. The arrangement of the weakening tool within the crash box part results in a space-saving and cost-saving design of the crash box by already existing space is preferably used to hold the weakening tool meaningful.

In order to increase the rigidity of the crash box part, the outer wall and / or the inner wall of the crash box part may have at least one stiffening geometry. Advantageously, the shape of the ribs can influence the cutting work on the one hand and the rigidity of the deformable crash box part on the other hand.

In a further embodiment of the invention, the outer wall and / or the inner wall of the crash box part is at least partially mechanically destroyed in the event of a crash by the at least one weakening tool in order to weaken the crash box part. This results in a cost-effective and simple realization of the setting of the energy absorption capacity of the crash box part, since an implementation of the crash box according to the invention with simple weakening principles is possible.

In a further embodiment of the invention, the at least one weakening tool comprises at least one destruction element and the destruction element controlling actuator unit, wherein the number of destructive elements used is variable depending on the desired energy absorption capacity of the crash box part. As a result, an adaptation of the weakening tool is possible in addition to both in terms of number and positioning of the destruction of the boundary conditions from the space limitations in an advantageous manner. In particular, due to the activation of the destruction elements by the actuator unit, an optimal setting of the weakening tool with regard to positioning and resulting cutting force of the destruction elements is possible.

In a further embodiment of the invention, the at least one destructive element is designed as a shearing and / or plastically deforming element, preferably as a knife element whose cutting angle and / or penetration depth is variably adjustable in dependence on the desired energy absorption capability of the Crashboxtei- les via the actuator. Here, the crash box part is intentionally destroyed or weakened by the knife element inside and / or outside, the cutting angle and / or penetration depth is preferably variably adjustable. Advantageously, the weakening tool is before and / or during the

Can be activated in case of a crash. In the event of a crash, this allows a controlled adjustment of the stiffness of the crash box part. With a greater weakening of the overall structure and a consequent reduction in the stiffness of the crash box part, the crash box or the crash box part can be deformed more strongly. With a smaller weakening of the overall structure and a resulting lower reduction of the stiffness of the crash box part, the crash box or the crash box part can be less deformed.

The crash box is preferably part of a bumper system. In an advantageous manner, this provides an adaptive front structure whose energy absorption capability can be adapted to the crash situation by adaptively configuring the stiffness of the crash box part. The stiffness of the crash box part of the crash box is adjusted before or during the crash, so that a higher energy absorption capacity of the front structure is ensured. In practice, this means, for example, that a soft front structure can be adjusted during intrusion of a pedestrian or a harder front structure during intrusion of a vehicle. In advantageous Accordingly, the crash box can be used in the field of partner protection, such as pedestrian protection, as well as in the field of self-protection.

An embodiment of the invention is illustrated in the drawings and will be explained in more detail in the following description.

Brief description of the drawings

1 shows a schematic plan view of a bumper system of a motor vehicle with two crash boxes according to the invention.

Fig. 2 shows a perspective view of an embodiment of a crash box according to the invention with a crash box part with a weakening tool for adjusting the energy absorption capacity of the crash box part.

3a to 3c each show a sectional view of another embodiment of the crash box part with a arranged in an outer wall of the crash box part stiffening geometry.

FIGS. 4a and 4b each show a sectional view of another embodiment of a destruction element of the weakening tool.

5 shows a diagram with possible force levels over the course of a deformation of the crash box part of an adaptive crash box according to the invention.

6 shows a schematic block diagram of a crash box system with a crash box according to the invention.

Embodiments of the invention

In the course of the development of passive safety in motor vehicles, self-protection is the first priority. This is the property of the motor vehicle to protect its own occupants both in vehicle-vehicle collisions and in collisions with other objects. For this example, crash boxes are used, for example. Such crash boxes for motor vehicles are known on the market and usually for the arrangement between see provided a bumper system and the body of the motor vehicle. The crash box is to be absorbed in the event of a crash in an impact of the motor vehicle energy to protect parts of the motor vehicle and the occupants of the motor vehicle. In general, the crash box is designed such that it is only reversibly deformed in a collision with very low speed of the motor vehicle, so that in this case no damage to the motor vehicle occur. In an impact at a slightly higher speed, the crash box advantageously absorbs so much energy that only the bumper system is damaged, but not the rest of the body of the motor vehicle. However, in the development of crash boxes, in addition to occupant protection, issues relating to partner protection and crash compatibility are increasingly coming to the fore. Partner protection is the property of the motor vehicle to protect the occupants of the opposing vehicle in a vehicle-vehicle collision, ie to have the least possible aggressiveness.

In Fig. 1, a bumper system 38 of a motor vehicle 12 is shown, which is connected to a body 40 of the motor vehicle 12. The body 40 has, for example, a plurality of longitudinal members 40a, with which the bumper system 38 is connected. The bumper system 38 has a cross member 38 a, which is connected to the longitudinal members 40 a of the body 40. In the event of a crash, the occurring forces are introduced via the cross member 38a of the bumper system 38 as evenly as possible via its connection points with the longitudinal members 40a in the body 40 of the motor vehicle 12 in an impact of the motor vehicle.

The connection of the cross member 38a of the bumper system 38 with the longitudinal members 40a of the body 40, as shown in Fig. 1, via a crash box system 1 1 with two crash boxes 10, on the one hand on the cross member 38a of the bumper system 38 and on the other hand on the corresponding side member 40a of the body 40 are attached. In this case, the body 40 of the motor vehicle 12 preferably has two longitudinal members 40a, a longitudinal member 40a being arranged in each case in a lateral edge region of the motor vehicle 12, and a crash box 10 being fastened to each longitudinal member 40a. In Fig. 1 by way of example a crash box system 1 1 is shown with two crash boxes 10, but also crash box systems 1 1 with only one crash box 10 or more than two

Crash boxes 10 are conceivable. FIG. 2 shows a crash box 10 according to the invention for a motor vehicle 12 in a perspective view. In the present exemplary embodiment, the crash box 10 according to FIG. 1 is part of a bumper system 38 of a motor vehicle 12. The crash box 10 comprises a crash box part 14 that is deformable in the event of a crash, either as part of the body 40 or as a separate component fixedly connected to the body 40 can be executed. Due to the deformation d of the crash box part 14, at least part of the crash energy F is absorbed by the work of deformation in the event of a crash. In the present exemplary embodiment, the crash box part 14 is preferably tubular or hollow.

Other geometries such as cone, cylinder, cylinders with elliptical cross section or rectangular or square shapes are conceivable.

In order to adapt a crash box 10 to the conditions prevailing in the event of a crash, such as crash severity and / or intrusion speed, the crash box 10 has at least one weakening tool 16 which weakens the overall structure of the at least one crash box part 14 in order to adjust the energy absorption capability of the crash box part 14 , whereby the rigidity of the crash box part 14 is reduced. Advantageously, an adaptation of the stiffness or the absorption of the crash energy F of the crash box 10 is thereby realized, on the one hand energy absorption by weakening work and on the other influencing the rigidity of the crash box part 14 of the crash box 10 by weakening the overall structure of the crash box part 14 and thus likewise an influence on the energy absorption takes place. It is noteworthy here that, depending on the design of the weakening tool 16 and the properties of the crash box part 14, more energy is absorbed by influencing the rigidity of the crash box part 14 of the crash box 10 than by the absorption of energy by the weakening work. In the present exemplary embodiment, the weakening tool 16 is arranged outside the crash box part 14 and acts on an outer wall 26 of the crash box part 14. Alternatively, the weakening tool 16 can also be arranged in a cavity 28 of the crash box part 14 and act outward on an inner wall 30 of the crash box part 14. That is, the weakening tool 16 is integrated in the crash box part 14 in this alternative embodiment. Advantageously, the outer wall 26 or alternatively the inner wall 30 of the Crashboxteiles 14 in the event of a crash, at least partially mechanically destroyed to weaken the crash box part 14.

In the present exemplary embodiment, the weakening tool 16 comprises at least one destruction element 34, 34a, 34b and one the destruction element 34,

34a, 34b activating actuator unit 24, wherein the number of destruction elements 34, 34a, 34b used is variable in dependence on the desired energy absorption capacity of the crash box part 14. The destruction element 34, 34 a, 34 b of the weakening tool 16 is controlled by the actuator unit 24 shown in FIG. 6 in a controlled manner.

The actuator unit 24 is responsible for changing the setting of the destruction element 34, 34a, 34b, wherein the number of actuator units 24 used and the destruction elements 34, 34a, 34b used can be adapted to the different requirements. The number may vary, for example, depending on the dimensions or vehicle size. The main requirement for the actuator unit 24 is speed. The destruction element 34, 34a, 34b is preferably infinitely adjustable or adjustable, but it is also an adjustment in several stages conceivable, if this is gained in speed. By the actuator unit 24, both the cutting angle α and the penetration depth t of the Zerstörelementes 34, 34a, 34b are changed, as shown in Fig. 4a and 4b. The change of the cutting angle α or / and the penetration depth t of the destruction elements 34, 34a, 34b can take place before the deformation d of the crash box 10. In addition, it is also possible to change the rigidity of the crash box 10 during the crash.

The actuator unit 24 may be mounted, for example, on the cross member 38a of the bumper system 38 or within the crash box member 14 on the side of the cross member 38a or on the side member 40a of the body 40 or within the crash box member 14 on the side of the side member 40a of the motor vehicle 12.

In the present exemplary embodiment, the destruction elements 34, 34a, 34b are preferably designed as knife elements whose penetration depth t according to FIG. 4a and / or cutting angle α according to FIG. 4b as a function of the desired

Energy absorption capacity of the crash box part 14 via the actuator unit 24 riabel is adjustable, wherein a small cutting angle α means that the blade element 34, 34a, 34b is set "flat" and thus less material removal takes place can thereby attack a large area of the crash box part 14.

The deformable crash box part 14 serves to absorb crash energy F by deforming itself plastically and irreversibly. In order to increase the rigidity of the crash box part 14, the outer wall 26 and / or the inner wall 30 of the crash box part 14 has at least one stiffening geometry 32, 32a, 32b, 32c.

In the present embodiment, the stiffening geometry 32 is ribs 32a, 32b, 32c in different shapes. The ribs may, for example, have the shape of longitudinal ribs 32a according to FIG. 2 and FIG. 3a, longitudinal ribs 32b with variable cross section according to FIG. 3b and ribs 32c which intersect according to FIG. 3c. By the shape of the ribs

32a, 32b, 32c, on the one hand, the cutting work, on the other hand, the rigidity of the deformable crash box part 14 can be influenced. The material pairing of crash box part 14 and blade elements 34, 34 a, 34 b can influence the quality of the adjustment of the energy absorption capability of the crash box part 14. The crash box part 14 is preferably made of plastic, although other materials are conceivable. Also, the execution of the crash box part 14 as a composite material conceivable. Possible embodiments would be, for example, 2-component plastic components with a so-called "hard" material for the rigidity and a so-called "soft" material for cutting or metal-plastic combinations. Also, a plurality of concentrically arranged cylinders, for example made of different materials can be used. The crash box part 14 may also have a generally thicker wall thickness instead of local stiffening ribs. This advantageously allows a simpler and thus more cost-effective production, but also a simpler installation of the crash box system.

FIGS. 3 a to 3 c show different embodiments of the crash box part 14. FIG. 3 a shows a crash box part 14 in the form of a tube with a longitudinal ribbing 32 a. FIG. 3b shows a crash box part 14 designed as a tube with a longitudinal ribbing 32b, which has a thickening cross section. FIG. 3 c shows a crash box part 14, designed as a tube, with longitudinal ribs 32 c extending itself cross. The longitudinal ribs 32c intersect here diagonally, resulting in different strength properties of the crash box part 14. When cutting the knife elements 34, 34 a, 34 b generate notches in the ribs 32 c.

6 shows a schematic block diagram of a crash box system 1 1 of a motor vehicle 12 having a crash box 10 according to the invention. As can be seen from FIG. 6, the motor vehicle 12 has a sensor system 20, an evaluation and / or control unit 18 and the crash box system 11 with the at least one crash box 10, the weakening tool 16 and the actuator unit 24, the crash box system 1 1 according to FIG. 1 being arranged between the bumper system 38 and the body 40 of the motor vehicle 12.

The sensor system 20 senses information about a vehicle environment, a crash severity and / or vehicle dynamics variables. A sensor unit 22 arranged in the region of the crash box part 14 determines the speed at which the crash box part 14 deforms in the event of a crash and transmits the information to the evaluation and / or control unit 18, which preferably uses the at least one weakening tool 16 as a function of the determined speed via the actuator 24 drives. The evaluation and / or control unit 18 receives the detected information from the sensor system 20 and / or from the sensor unit 22 and evaluates the received information for the adaptive adjustment of the energy absorption capacity of the crash box part 14, wherein the evaluation and / or control unit 18, the determined current driving situation evaluates to the effect whether an activation of the weakening tool 16 of the crash box system 1 1 is required or not. The received information about driving dynamics variables in conjunction with the information from the vehicle environment and / or the Crashboxbereich allow the evaluation and / or control unit 18 is a predictive control of the weakening tool 16. In addition, the control can also be performed in dependence on information that the vehicle via a communication system from outside, ie from other road users, traffic control centers, etc. The sensor unit 22 is preferably integrated as one into the crash box 10

Speed measuring device executed, for example as a Ra dareinheit. In addition to the low cost, the sensor unit 22 also provides further prerequisites to meet the requirements with regard to accuracy and speed in the setting of the weakening tool 16. This small radar sensor 22 can determine the distance with high accuracy, in one dimension, in this case axially, and also the distance change, ie the speed with a very high sampling rate. Thus, at a very early time after the crash, the speed at which the crash box 10 deforms initially can be determined. As already mentioned, the sensor system 20, which is preferably designed as a pre-crash sensor system and / or communication system, can also provide the input for setting the crash box 10. The signal could therefore also come from a mono or a stereo video sensors, a radar sensor, a lidar sensor or a CV sensor (Closing Velocity Sensor) and / or via a communication system from outside, ie from other road users, traffic control centers and so on. Advantageously, this could be used in front structures of motor vehicles 12, so-called

Upfront sensors either saved or integrated directly into the crash box 10.

The control of the weakening tool 16 can take place in dependence on a signal from the evaluation and / or control unit 18. Preferably, the evaluation and / or control unit 18 is executed in the form of a control unit, which is designed for example as an airbag control unit, with other control units for control are conceivable. Preferably, the evaluation and / or control unit 18 is designed as part of the airbag control unit, which entails a cost advantage. An execution of the evaluation and / or

Control unit 18 as a separate control unit, would advantageously allow a higher modularity. However, such a separate intelligence would have to be placed in such a way that it would be protected in the event of a crash. As has already been explained above, the evaluation and / or control unit 18 provides for the detection of information from the sensor system 20 and / or the sensor unit 22, ie the evaluation and / or control unit 18 of the motor vehicle 12 evaluates the adaptive control of the Weakening tool 16 data of the sensor system 20 and / or the sensor unit 22, which includes information about the vehicle environment and / or crash severity and / or the speed at which the crash box part 14 deforms in the event of a crash. An evaluation algorithm generates a corresponding signal, which Chung tool 16 in response to the determined information via the actuator 24 drives. The crash box 10 according to the invention preferably offers the possibility of acting on the weakening tool 16 in a feedback manner not only before the crash or shortly thereafter, but also during the entire course of the crash.

Before and during the crash or the collision, the sensor system 20 senses information about a vehicle environment, an impact and / or vehicle dynamics parameters and sends a corresponding control signal to the actuator unit 24 for activating the attenuation tool 16 of the crash box 10

Signal may be a voltage and / or information, such that the actuator 24 generates an actuating signal for the destruction elements 34, 34a, 34b, 34c, which with the predetermined cutting angle α on the actuating signal and / or with the predetermined depth of penetration via the control signal t acts on the crash box part 14.

Preferably, the weakening tool 16 can be activated before and / or during the crash. If a potential impact is detected by the forward-looking sensor system 20, the actuator unit 24 activates the destruction elements 34, 34a, 34b, 34c of the weakening tool 16, the intensity of the weakening of the overall structure of the crash box part 14 or the cutting angles .alpha. And / or the Penetration depth t of the destruction elements 34, 34a, 34b, 34c preferably as a function of a recognized object, the relative speed of the vehicle, the speed at which the crash box 14 deforms in the event of a crash, and / or the crash type are set by the actuator 24 targeted can. The adaptive crash box 10 according to the invention is designed in such a way that, in the event of a fault, it is always possible to fall back on the maximum rigidity of the crash box part 14 and thus on the maximum self-protection. The activation of the weakening tool 16 is independent of possible misdetections of the predictive sensor system 20, since the destruction elements 34, 34a, 34b, 34c are switched off again after failure of a crash after a defined time by the actuator unit 24. Preferably, the activation of the destruction elements 34, 34a, 34b, 34c during a crash operation and in particular during a multiple crash operation is specifically controllable and / or constant. The functioning of the adaptive crash box 10 can be described with the following steps:

In a first optional step, the sensor system 20 preferably recognizes a pre-crash sensor system of impending crash and may be more ideal

Differentiate between a standing and a moving object. Preferably, the sensor system 20 can also determine the size of the stationary or moving object.

In a second step, the motor vehicle 12 has contact with the object or obstacle. The deformation of the Fronstruktur in the region of the cross member 38a begins. The cross member 38a deforms the crash box part 14 of the crash box 10. At the beginning, the deformation d is still elastic, as shown in FIG. 5 curve section a can be seen. In a third step, the preferably crashbox-internal sensor unit 22 detects the deformation d and its speed. In a fourth step, the evaluation and / or control unit 18 assesses the severity of the crash and decides on the required rigidity or strength of the crash box 10, wherein the evaluation and / or control unit 18 either as a separate control unit in the adaptive crash box or part of a Airbag control unit of the motor vehicle is executed. In a fifth step, the evaluation and / or control unit 18 outputs a corresponding signal to the actuator unit 24, which adjusts the destruction elements 34, 34a, 34b of the weakening tool 16 as a function of the crash type or not. In a sixth step, the plastic deformation of the crash box 10 begins, with different cases for this.

In a first case, the evaluation and / or control unit 18 registers a serious crash. It must be utilized according to FIG. 5 curve section b1, the entire rigidity of the crash box 10. The destruction elements 34, 34a, 34b of the weakening tool 16 are set under the keyword self-protection so that as much energy as possible is destroyed. The deformation d goes well beyond the crash box 10. In the side member 40a, more energy is absorbed according to FIG. 5 curve section c1. In a second case, the evaluation and / or control unit 18 registers a medium-severity crash. Here comes under the keywords crash compatibility, Partner protection and self-protection only a part of the destruction elements 34, 34a, 34b are used. The stiffness or strength of the crash box 10 is targeted and reduced in favor of the accident opponent to reduce the energy as optimally as possible. It is the Crashbox shown in FIG. 5 curve section b2 and a part of the longitudinal member 40a of FIG. 5 curve section c2 deformed.

In a third case, the evaluation and / or control unit 18 registers a slight accident. The destructors 34, 34a, 34b of the debulking tool 16 are described under the terms repair crash, i. 16km / h against a rigid barrier, and pedestrian protection adjusted so that only the crash box 10 is deformed. It is shown in FIG. 5 curve section b3 only the crash box 10 deformed, the longitudinal member 40a remains intact.

The curve shown in FIG. 5 is subdivided into the three segments described below. Segment a represents the initial area of the crash box 10. This is an elastic area. This characteristic is always the same regardless of the individual crash box settings. Segment b shows different stiffness settings of the crash box 10, although other settings than b1, b2, b3 are possible. Segment c represents the longitudinal member 40a, which is deformed more or less (or not at all) depending on the crash severity. This characteristic is always the same.

An essential advantage of the invention is that the adaptive crash box according to the invention is a so-called dry system. This means that no liquids are used here. Since it is a dry system, elements such as hydraulic pumps, valves for adaptability, hydraulic lines or hydraulic accumulators can be omitted. In particular, leakage problems over the life of the vehicle are eliminated and no environmental aspects regarding toxic fluids are to be considered. A dry solution is therefore not only lighter, but also space-saving, cost-effective and environmentally friendly.

A further advantage of the invention lies in the fact that the adaptive crash box 10 offers an optimum solution, in particular in offset crash. The adaptive crash box 10 shows its advantages over a non-adaptive especially in offset crash

Solution. Since the system is equipped with a sensor system 20 and / or a sensor unit 22, for example, a radar unit is equipped, can be differentiated, whether it is a collision against a wall without offset (eg

USNCAP at 56 km / h) or overlap collision (e.g., Euro NCAP at 64 km / h, 40% overlap to the barrier). In the case of overlap, the affected longitudinal member 40a of the body 40 and the crash box 10 must break down almost all of the crash energy F and thus be very rigid, with the adaptive crash box being set to "stiff." On the other hand, both longitudinal members 40a of the body 40 and both Crash boxes 10 of the crash box system 11, the adaptive crash boxes 10 can be made "softer" in order to dissipate more energy along the way without causing high peak loads.

Claims

claims

1 . Crash box (10) for a motor vehicle (12) with at least one crash box part (14) deformable in the event of a crash, which absorbs energy in the event of a crash by the deformation (d), characterized by at least one weakening tool (16) which is used to adjust the energy absorption capability of the crash box part ( 14) weakens the overall structure of the at least one crash box part (14), whereby the rigidity of the crash box part (14) can be reduced.

2. crash box according to claim 1, characterized in that an evaluation and / or control unit (18) in the motor vehicle (12) for adaptive adjustment of the energy absorption capacity of the crash box part (14) evaluates data of a sensor system (20), which information about vehicle environment and / or crash severity.

3. crash box according to claim 1 or 2, characterized in that in the region of the crash box part (14) arranged sensor unit (22) determines the speed at which the crash box (14) deforms in the event of a crash, and to the evaluation and / or Control unit (18) transmits, which preferably drives the at least one weakening tool (16) in response to the determined speed via an actuator unit (24).

4. Crashbox according to one of claims 1 to 3, characterized in that the at least one weakening tool (16) outside of the crash box part (14) is arranged and on an outer wall (26) of the crash box part (14) acts and / or that at least one Weakening tool (16) is arranged in a cavity (28) of the crash box part (14) and acts on the outside on an inner wall (30) of the crash box part (14).

Crashbox according to one of claims 1 to 4, characterized in that the outer wall (26) and / or the inner wall (30) of the crash box part (14) has at least one stiffening geometry (32, 32a, 32b, 32c).

Crash box according to one of claims 1 to 5, characterized in that the at least one weakening tool (16) the outer wall (26) and / or the inner wall (30) of the crash box part (14) in the event of a crash at least partially mechanically destroyed to the crash box (14 ) to weaken.

Crash box according to one of claims 1 to 6, characterized in that the at least one weakening tool (16) comprises at least one destruction element (34, 34a, 34b) and the destruction element (34, 34a, 34b) actuating actuator unit (24), wherein the Number of destruction elements (34, 34a, 34b) used is variable depending on the desired energy absorption capacity of the crash box part (14).

Crash box according to one of claims 1 to 7, characterized in that the at least one destructive element is designed as a shearing and / or plastically deforming element (34a) preferably as a knife element (34, 34b) whose cutting angle (a) and / or penetration depth ( t) depending on the desired energy absorption capability of the crash box part (14) via the actuator unit (24) are variably adjustable.

Crash box according to one of claims 1 to 8, characterized in that the weakening tool (16) can be activated before and / or during the crash.

10. Crashbox according to one of the preceding claims, characterized in that the crash box (10) is part of a bumper system (38).