FIELD OF THE INVENTION

The invention relates to an implementation that provides the connection on the bumper and also provides an increase in strength in these regions, especially for brackets which are components such as sensors or clips are mounted on the bumper.

PRIOR ART

Bumpers are surfaces/items that are used especially in the front and rear parts of vehicles and are usually the first contact area at the time of collision. There are bumper bars and shock absorbing components in the behind of the bumpers, and they provide the absorption of some of the energy in this area in the event of a collision. Bumpers, on the other hand, are among the vehicle body components that provide visual aesthetics to the vehicle by closing these areas, prevent damage in case of collision by closing sharp corners, and absorb some of the energy at the same time.

In the known art, bumpers are made of plastic material and have the ability to stretch. However, it is damaged by breaking when the stretch threshold value is exceeded.

Vehicles have some equipment with the developing technology. Especially sensor components that increase driving safety, fog lights, daytime running lights are usually mounted on bumpers. Considering the sensor applications, the slots that allow the sensors to be attached to the bumper, and the slots to fix the clips that enable the cables connect to the sensors to be mounted on the bumper are formed at the stage of the polymer injection molding process in a single piece with the bumper.

There is no known technique or application on the vehicle, that increases the strength in these areas, absorbs the energy in the event of an impact or prevents the bumper from breaking. In addition, there are areas on the vehicle bumpers that increase strength and act as shock absorbers. There are shock absorbing components in these areas. The structure and shape of the mentioned components vary for each vehicle. This is a result that increases the production cost.

As a result, all abovementioned problems have made it necessary to make an improvement in the relevant technical field.

AIM OF THE INVENTION

The present invention aims to eliminate the abovementioned problems and to make a development in the relevant technical field.

The main objective of the invention is to reveal the multi-layered structure, which increases the strength in the bracket regions that enables the mounting of the sensor and cable clips in the bumpers of the vehicles, and also provides energy absorption that ensures the fixing of the mentioned brackets to the bumper after the bumper production

Another objective of the invention is to provide an alternative solution to the shock absorbing elements used in large areas on the bumper.

Another objective of the invention is to create a multi-layered shock absorber structure that can be integrated directly on the bumper, as an alternative to bumper shock absorber elements that vary for each vehicle types/model.

Another objective of the invention is to prevent breakage/cracking in the impact areas of the bumper in small impact/collision.

In the preferred embodiment of the invention, the structure that provides the adhesion between the base layer, the intermediate layer and the top layer is self-renewing, and small-scale cracks can be repaired by exposure to UV light. In this way, it can be repaired quickly in daylight or by applying UV light to the surface.

BRIEF DESCRIPTION OF THE INVENTION The invention is related to shock absorbing-stiffening multi-layer structure for bumpers so as to fulfil all aims mentioned above and will be obtained from the following detailed description.

The invention relates a method in vehicles, especially on the bumpers to enable mounting of sensor clip or absorber on the inside of the bumper inside of the bumper which increases the strength and creates an impact damping effect in the designated mounting regions of said bumper and feature characterized by implementation of process steps; in the strength-enhancing component consisting of tapes with unidirectional extending fibrous structure, consisting of at least three layers, that are the base layer, the interlayer, the top layer, positioning at least one insert between at least two consecutive layers of said layers, positioning at least one bracket in order to mount components between at least two consecutive layers of said layers, curing mentioned layers with UV light during the application.

In a preferred embodiment by means of the invention, a method is presented that ensures the orientation of the impact and the cracking in the desired region and direction by adjusting the placement and stiffness of the layers during the impact damping effect.

In a preferred embodiment of the invention, haves the process of applying at least one layer of adhesive interlayer between two successive layers, after the curing process of the previous layer to apply an upper layer when forming a unidirectional fibrous structure consisting of at least three layers as the base layer, the interlayer, the top layer.

In a preferred embodiment of the invention, that includes a unidirectional extending fiber component, which is UD tape.

In a preferred embodiment of the invention, that consists of providing multi-directional strength the unidirectional fiber components by laid in different directions, which are UD tapes. (Etc. 0°-90°, 0°-45°-90°-135° Angles.)

In a preferred embodiment of the invention, the absorber that is located on the strength increasing component on the bumper is integrated between the layers during the formation of the said strength increasing component.

In a preferred embodiment of the invention, where the absorber on the strength increasing component on the bumper is mounted on the insert integrated between the layers during the formation of the said strength increasing component. In a preferred embodiment of the invention, wherein each layer is cured using a Xenon lamp during the formation of the strength enhancing component.

In a preferred embodiment of the invention, curing processes are applied with UD tapes and using Xenon lamp on the bumper using a 5-axis robot.

In a preferred embodiment of the invention, the inserts that contains bolts are positioned between the two layers during the formation of the strength increasing component to enable direct mounting of the components.

The protection scope of the invention is specified in the claims and cannot be limited to the description made for illustrative purposes in this brief and detailed description. It is clear that a person skilled in the art can present similar embodiments in the light of the above descriptions without departing from the main theme of the invention.

BRIEF DESCRIPTION OF DRAWINGS

In Figure 1 , the representative drawing of the system in which the invention is applied is given.

In Figure 2, the cross-sectional view of the structure which is the subject of the invention is given.

In Figures 3A, 3B and 3C alternative solutions applied on the bumper during the application of the invention is given.

In Figure 4, a representative cross-sectional drawing of another preferred embodiment of the invention is given.

DESCRIPTION OF THE REFERENCES IN FIGURES

10. Base layer

20. Interlayer

30. Top layer 40. Insert

50. Bracket

60. Cable

70. Adhesive interlayer

A. Absorber

B. Bumper

C. Clip

R. Strength-enhancing component

S. Sensor

DETAILED DESCRIPTION OF THE INVENTION

In this detailed description, the invention multilayered shock absorber structure for bumpers (B) is described by means of examples only for clarifying the subject matter such that no limiting effect is created.

The invention relates to the strength-enhancing component (R) ant its use, which is a multi-layered structure that acts as a shock absorber in these regions, while provides the connection on the bumper especially for brackets which are components such as sensors or clips are mounted on the bumper.

A method in vehicles, especially on the bumpers (B), to enable mounting of sensor (S), clip (C) or absorber (A) on the inside of the bumper (B) inside of the bumper (B), which increases the strength and creates an impact damping effect in the designated mounting regions of said bumper (B) and feature characterized by implementation of process steps; in the strength-enhancing component (R), consisting of tapes with unidirectional extending fibrous structure, consisting of at least three layers, that are the base layer (10), the interlayer (20), the top layer (30), positioning at least one insert (40) between at least two consecutive layers of said layers, positioning at least one bracket (50) in order to mount components between at least two consecutive layers of said layers, curing mentioned layers with UV light during the application.

In Figure 2, the representative cross-section of the multi-layered structure, which is the subject of the invention, is given. The multi-layered structure of the invention includes at least one base layer (10) that will contact the bumper (B) surface directly. There is an interlayer (20) on the said base layer (10). In the uppermost part of the structure, the top layer (30) is located. In the inner part of the interlayer (20), there is at least one insert (40) structuring to be positioned between the base layer (10) and the top layer (30). The layers are directly welded with each other in the mentioned configuration.

Said base layer (10) can be mounted to the bumper (B) with an adhesive additional layer or using Ultrasonic or ultraviolet welding surfaces on the surface of said base layer (10) that is contacting with the bumper (B).

Figure 1 shows, a representative drawing that is the implementation of the invention. The base layer (10) contacts the inner surface of the bumper (B). On the base layer (10) in the configuration described above at least one insert (40) configuration is located in the inner part of the interlayer (20), between the base layer (10) and the top layer (30). There is the top layer (30) structure on the top surface. Within the scope of the invention, brackets (50) can be fixed on the said insert (40) in the multi-layered structure obtained to form the strength-enhancing component (R). In the preferred embodiment of the invention, each said bracket (50) is adhered directly onto the insert (40) together with the top layer (30).

As seen in Figure 1 , the sensor (S) can be positioned on each bracket (50) and/or at least one clip (C) that is positioned on the bracket (50) the cables (60) can be fixed on the bumper (B) according to the usage area of the bracket (50).

Within the scope of the invention, with the strength-enhancing component (R), an absorber (A) is integrated into the regions where the brackets (50) must be positioned on the bumper (B) by design. In addition, the said strength-enhancing component (R) can be applied to different desired areas of the bumper (B). In this way, absorber (A) adaptation, which can be adapted to all bumper (B) configurations regardless of product design, can be achieved. In the preferred embodiment of the invention, the base layer (10), the interlayer (20) and the top layer (30) are preferably made of PET and/or biopolymer material.

In the preferred embodiment of the invention, the base layer (10), the interlayer (20) and the top layer (30) contain unidirectionally extending fibrous structure. Preferably, said base layer (10), interlayer (20) and top layer (30) are UD tape.

In another preferred embodiment of the invention, the base layer (10), the interlayer (20) and the top layer (30) contain unidirectionally extending fibrous structure. And these structures can be placed at different planar angles and provide strength in different directions.

Application of invention

The strength-enhancing component (R) of the invention can be applied to the vehicle bumper (B) especially to the desired parts in accordance with the forms shown in figure 3 A, figure 3 B and figure 3 C.

In this context, the base layer (10) is applied to the desired area of the bumper (B) as first layer. Subsequently, the said layer is rapidly cured under UV light. Afterwards, the insert (40) that is suitable for the area of usage is located and the interlayer (20) is applied as second layer on the base layer (10) and the insert (40). Similarly, the said interlayer (20) is cured under UV light and the top layer (30) is applied on it as the third layer. With the curing of the top layer (30) with UV light, the strength-enhancing component (R) becomes ready.

In a preferred embodiment of the invention, brackets (50) that is suitable for clip (C) or sensor (S) mounting can be applied directly or together with the insert (40) on the base layer (10). Other layers can be applied on this structure after the curing process of the base layer (10).

In a preferred embodiment of the invention, it is possible to mount components with different desired features on the bumper (B) by using functional inserts (40). For example, a component suitable for the structurally used insert (40) in this region can be mounted by using an insert (40) containing a bolt or nut on the bumper (B),

Within the scope of the invention, said base layer (10) is fixed on the bumper (B) with the curing of the base layer (10). In the preferred embodiment within the said fixing process, the base layer (10) is welded with the bumper (B) material (plastic). In an alternative embodiment, the base layer (10) adheres to the bumper (B) in a high strength.

In the preferred embodiment of the invention, there is an adhesive interlayer (70) between the layers that are the base layer (10), the interlayer (20) and the top layer (30). Said adhesive interlayer (70) is the adhesive applied between the layers. In the preferred embodiment, said adhesive interlayer (70) may be resin-based.

In the preferred embodiment, structure can become stable by increasing its effectiveness during the curing of the layer which is located on the adhesive intermediate layer (70).

In the preferred embodiment of the invention, the inserts (40) are made of steel material. In other preferred embodiments, hard plastic or composite materials can be used.

In the preferred embodiment, a Xenon light source used for curing as a light source.

In Figure 3A, the structure of the absorber (A) that is fixed to the bumper (B) with the strength-enhancing component (R) with increased shock absorbing feature is given within the scope of the invention. In this context, the absorber (A) can be positioned directly on the base layer (10) together with the insert (40) or preferably without using the insert (40). said absorber (A) merges with the bumper (B) with the curing of the base layer (10) and/or the interlayer (20).

In Figure 3B, a representative drawing showing the application of the clips (C) on the bumper (B) within the scope of the invention is given. In this scope, the clip (C) holding bracket (50) is positioned directly on the base layer (10) or the insert (40) positioned to lower section of the bracket (50) during the formation of the layers, and the layers are cured within the scope of the above-mentioned process steps. Similarly, in figure 3C shows, common usage of configuration the sensor (S) and clip (C) application together. Similar to the clip (C) process, the sensor (S) holding brackets (50) that enables the sensors (S) to be held are positioned on the base layer (10) with the insert (40) at the bottom or directly positioned/adhered on the bumper (B) during the curing processes, and then other layers are formed on the upper part and the curing processes are completed.

In the preferred alternative embodiment of the invention, the strength-enhancing component (R) structure, which is in the form of the above-mentioned base layer (10) - adhesive interlayer (70) - interlayer (20) - adhesive interlayer (70) - top layer (30) can be more than three main layers by increasing the number. In this context, an adhesive interlayer (70) can be used in between the layers or direct application can be made one layer top of other layer.