SE0900992A1 - Fastener and use of fastener - Google Patents

Abstract

The present invention relates to a fastening device (1) for energy absorption comprising two fastening parts (2) and an expansion part (3), wherein the expansion part (3) has an extension direction between said fastening parts (2) arranged on opposite sides of the expansion part (3). . The expansion part (3) comprises at least one net-shaped pattern (5) of continuous link portions (8) which meet at nodes (6, 6 '), at least a first imaginary straight line (L1) along a link portion (8) extending between two nodes (6, 6 ') connected by said link portion (8), said line (L1) being arranged at an angle (a) to the direction of extension of the expansion part. Publication figure: Fig. 1

Description

15 20 25 30 2 the module unit in a “worst case scenario” if it is not securely attached to the vehicle break through to the driver's cab and thereby also cause personal injury.

As I said, ordinary angle brackets are often used together with, for example, screws, bolts or other suitable fixing elements to fasten the modules to the wall. These angle brackets and fixing elements are exposed to very large forces during heavy braking. The weakest link is often the interface to the car or the fixing element, where e.g. the screw breaks off before the energy in the heavy braking is exhausted and the module can thus break loose and cause damage. To reduce the risk, a safer system is therefore needed for attaching modular systems / units in vehicles.

It is already known to use energy-absorbing fastening elements to fasten e.g. a safety barrier / net in a cargo space, where cargo moves forward and strikes the barrier / net during heavy braking.

The fastener can then absorb parts of the force. WO96 / 06756 and US20070035158 disclose such energy absorbing fasteners.

Such fasteners can be complicated to manufacture in order to obtain the desired energy absorption and may require a certain space between the wall and the interior to be mounted. This space can possibly cause additional furnishings to not fit, as you only have a limited space in the cargo space.

Thus, there is still a need for an alternative fastener that can absorb energy.

Summary of the Invention The present invention has for its object to meet the above needs. This object is achieved according to the invention in that the device of the initially stated type comprises a fastening device for energy absorption comprising two fastening parts and an expansion part, the expansion part having an extension direction between said fastening parts arranged on opposite sides of the expansion part. The expansion part comprises at least one net-shaped pattern of continuous link portions which meet in nodes, at least a first imaginary straight line along a link portion extending between two nodes connected by said link portion, said line being arranged at an angle to the expansion part extent of extension. Through this net-shaped pattern, you get a fastening device that can effectively absorb the energy that arises during, for example, a sharp deceleration. You can also get a stable energy absorption. The net-shaped pattern makes it possible to utilize the material efficiently and it also means that the weight of the fastening device can be less than with, for example, an ordinary angle iron.

Suitably the angle between the first line and the direction of extension of the expansion part is greater than 45 ° and suitably greater than 60 °.

By having a larger angle to the direction of extension of the expansion part, a longer link section can be obtained (depending, among other things, on the positioning of the nodes relative to each other) and with a large angle the nodes can be moved a longer distance in the expansion section direction than if the link section was short and / or had been small already in the initial situation.

The entire fastening device can thus be extended further. Suitably, the expansion part expands when the fastening device is exposed to and exceeds a predefined force, whereby the nodes are moved relative to each other. By predefining a force that the fastening device must be able to absorb, the construction of the expansion part can be adapted, ie. blah. the mesh-shaped grid pattern so that the expansion part expands in the direction of extension of the expansion part when this force is exceeded. However, this force should be less than the maximum capacity of the fastener.

Suitably, said imaginary line moves from its first angle to a second angle, which second angle is smaller than said first angle measured from the direction of extension of the expansion part.

Suitably the net-shaped pattern of continuous link portions meeting at nodes is limited by boundary portions, preferably in the form of recesses, two adjacent boundary portions arranged at a distance from each other across the extension direction of the expansion part being arranged at a distance from at least one further boundary the direction of extension of the expansion part, which limiting portions are evenly displaced in relation to each other across the direction of extension of the expansion part. By arranging * CïLšl. «8Y'-E§“ f'âší \, = ii ~~ iš ~ í 21: ri 10 15 20 25 30 4 at least some of the boundary portions as described above, one obtains an at least partially homogeneous area as the force This homogeneous area means that forces are evenly distributed within this area. If all limiting portions are arranged like this over the entire surface of the expansion part in the direction of extension of the expansion part, a homogeneous expansion part is obtained where the force is distributed evenly over the entire expansion part. The force equilibrium means that the force is the same along the entire extent.

Suitably, the reticulated pattern of contiguous link portions meeting at nodes is limited by at least one recess.

The advantage of recesses is that they are easy to manufacture. They can e.g. punched or cut out if a flat material is used or they can be formed directly in the manufacturing process if the expansion part is cast, for example.

The recesses can have an oval shape. Preferably, the oval recess has a largest extent extending across the direction of extension of the expansion member. At least one of the recesses may have a substantially rectangular shape. Suitably, the rectangular recess has a largest extent extending across the direction of extension of the expansion member. At least one of the recesses may be a slit. Conveniently, the recess, which is shaped like a slit, has an extension extending across the direction of expansion of the expansion member. Because the recesses have a largest extent across the direction of expansion of the expansion member, the intended straight line may have a greater angle to the extension direction of the expansion member. . The link section can also be longer. This provides the benefits mentioned earlier.

Preferably, the recesses have rounded corners. By having round corners, it is avoided that fractures occur through crack formation in the corners of the recesses when the expansion element expands, ie. pulled out.

Preferably, the expansion part is flat. A flat expansion part makes the manufacture of the expansion part simple. The recesses can then be punched / cut etc. out in the same manufacturing step as when making the actual expansion part.

Preferably, at least one of said two fastening portions is flat. Flat mounting parts are easy to manufacture. In addition, if the expansion part is flat, the fastening device can be manufactured as a part from one and the same material. Which saves manufacturing time and costs. At least one of the fastening portions can be arranged at an angle to the expansion part. By angling the fastening portions, the fastening device can be easily adapted to the environment in which it is to be mounted.

Suitably the expansion part and / or at least one of the fastening portions is of a hardening metallic material. The advantage of such a material is that if a point / area in the material is loaded and deformed, this point / area will harden and since the material next to it is weaker, it means that the deformation is moved there. Gradually, "all" material becomes involved and thus deformed, which means that it takes a long time before there is a localization of deformation that leads to fracture. You can thus absorb more energy than if a material without a hardened effect is used. For example, the stainless material EN 1.4301, AlSl 304 or EN 1.4307, AlSl 304L from the supplier Outo Kumpu or Domex 220 from the company SSAB can be used.

Suitably, at least one fastening device as described above is used to fasten the interior to a wall of a service vehicle.

Various other features appear from the following description given with reference to the accompanying drawings which show embodiments and realizations of the invention as non-limiting examples.

Brief Description of the Drawings The invention will be described in more detail in the following with reference to the accompanying schematic drawings which, by way of example, show presently preferred embodiments of the invention.

Fig. 1 shows an open perspective view of a service vehicle comprising a modular system with fastening devices according to the invention.

Fig. 2 shows a perspective view of the fastening device according to the invention attached to a wall and to a part of a modular system, Fig. 3a shows a fastening device according to the invention in a first embodiment with the expansion part shown from the front view.

Fig. 3a 'and Fig. 3a "show a part of the fastening device in Fig. 3a Fig. 3b shows the fastening device in Fig. 3a seen in perspective. Fig. 3c shows the fastening device in Fig. 3a in an expanded state in perspective.

Fig. 3d shows a part of the expanded fastening device in fig. 3c with the expansion part shown in front view.

Fig. 4a shows a fastening device according to the invention in a second embodiment in a front view.

Fig. 4b shows the fastening device in fig. 4a seen in perspective.

Fig. 5a shows a fastening device according to the invention in a third embodiment in a front view.

Fig. 5b shows the fastening device in Fig. 5a seen in perspective.

All figures are extremely schematic and not necessarily to scale. They show only parts which are necessary to explain the invention, other parts are omitted or only suggested.

Description of Preferred Embodiments The above as well as additional parts, features and advantages of the present invention will be better understood from the following illustrative and non-limiting detailed description of preferred embodiments of the present invention with reference to the accompanying drawings in which like reference numerals will be used. .

Fig. 1 shows a motor vehicle, e.g. a service vehicle 10 with a modular system 11 arranged in the cargo space 20 of the service vehicle 10.

The module system 11 has a frame construction which is built up of rails 15 in which drawers 12 are arranged. Shelves or other modules can also be arranged therein. However, the modular system 11 is not limited to this structure. It can have any construction. The module system 11 is located on the floor 13 and may be attached thereto. The module system 11 is attached to the wall 14 with a plurality of fastening devices 1. Fig. 2 shows more clearly how the module system is connected to the wall. lfig. 1 shows two fastening devices 1. Both are arranged on one side of the module system 11 against the rear part of the cargo space 20, but several can be arranged on the other side of the module system 11 or somewhere in between. A fastening device 1 is arranged on the upper part åßi. ~ Âï * rfšï'íilifš to If? Fig. 2 shows the fastening device 1 arranged to a rail 15 which is part of the modular system 11 which is part of the modular system 11 which is part of the modular system 11 which is part of the modular system 11 which is part of the modular system 11 which is part of the modular system 11. is shown in Fig. 1. The fastening device 1 is arranged to the rail 15 with a bolt 16 by means of, for example, a nut (not shown). The nut is here arranged in the rail 15 in an undercut groove 17. All conceivable ways of mounting a fastening device to an interior or to a wall are possible. It is not limited to a rail with an undercut groove in which a nut is arranged. The fastener 1 is then attached to the wall 14 with an additional bolt 16. The fastener is not limited to being attached to either the wall or the modular system in this manner. For example, screws, rivets, quick fasteners can be used. The end of the fastening device shown here as mounted on a wall can also be mounted on parts other than a wall, for example on an intermediate part such as an inner wall or at a distance from the wall or on another modular system. All possible options that are suitable are possible. The fastening device 1 can also be used to fasten interiors other than modular systems, such as cabinets, drawers, etc.

Figs. 3a and 3b show the fastening device 1 in a front view and a perspective view, respectively. Fig. 3 a 'and Fig. 3a "show a part of Fig. 3a. The fastening device 1 consists of two fastening parts 2 and an intermediate part 3. The intermediate part is an expansion part 3, i.e. when the fastening device 1 is subjected to a force which arises by, for example, sharp braking of the vehicle in the event of a collision, for example, the force / energy will be absorbed by the expansion part 3 by extending the expansion part 3 when the force exceeds a certain value for which the expansion part 3 is optimized.

The expansion part 3 has an extension direction between said fastening portions 2, which are arranged on opposite sides of the expansion part 3.

The direction of extension is shown in Fig. 3a "as the line L. The fastening device 1 is suitably constructed so that when it is arranged in the vehicle, the direction of extension of the expansion part is substantially in the direction of travel of the vehicle.

Which is the same direction that the force will come in during a heavy deceleration. In the coordinate system of Fig. 3a, the direction of extension of the expansion part is in the x-direction and the direction across the direction of extension of the expansion part is in the y-direction. The fastening portions 2 each have a fastening point 21. Here, the fastening point 21 is a through hole, in which a fixing element can be implemented. Such a fixing element can be, for example, a screw, bolt, rivet or a quick-release fastener. Attachment 21, however, is not limited to being a hole.

It may be some kind of device which is suitable for attaching the fastening device to the wall or the interior and they may be different on the two fastening portions.

The expansion part 3 and the fastening portions 2 are flat and made together from one and the same material in order to have as simple a manufacturing fastening device as possible. However, the expansion part 3 and the fastening portions 2 are not limited to being flat and / or of one and the same material and they can be made separately and then assembled. The fastening portions 2 are arranged on opposite sides of the expansion part 3 and each at an angle to the expansion part 3. These angles are determined by where on the wall 14 in the vehicle 10 and where on the module system 11 the fastening device 1 is to be fastened (fig. 1). Through this construction, it is possible to make different variants of the fastening device in an easy and cost-effective manner, which can be adapted to special vehicles and / or interiors. The expansion part 3 has a net-shaped pattern 5 of continuous link portions 8 which meet at nodes 6, 6 '. The net-shaped pattern 5 is limited by limiting portions 7, 7 ', preferably in the form of recesses.

The boundary portions 7, 7 'can also be non-continuous depressions (not shown) from one or both sides of the expansion part 3. The net-shaped pattern is further described from a perspective where recesses 7, 7' limit the appearance of the net-shaped pattern. Thus, the recesses 7, 7 'have the same reference number as the limiting portion 7, 7'. The recesses 7, 7 'are arranged in different rows R1-R11 across the direction of extension of the expansion part.

The direction of extension of the expansion part is, as stated, the direction in which the expansion part 3 will extend when it is subjected to a force.

Every other row has the same design as row one R1 and every other row has the same design as row two R2. Ie. R1, R3, R5 etc. have one design and R2, R4, R6 etc. have a different design. From now on, reference will only be made to line one R1 and line two R2, but the features also apply to the other lines. However, the expansion part 3 is not limited to this, each row “U å, lf-šfßjl ëålxil 'ír-št fl l 3 1221Qàšêâšliwègzpâfa; atzorætexi, _.š ~ a:' j1 tvlfitf: 10 15 20 25 30 9 may have its own design or only certain lines can have the same design.

All recesses 7, 7 'have a rounded shape, such as for example an oval shape illustrated here. Each row has two recesses. The recesses on each row are evenly distributed over the expansion part, ie the distance between the recesses is equal.

However, the expansion part 3 is not limited to two recesses or to the oval shape or to everyone having the same shape, but one can have only one or more recesses on each row and they can have different distances between them. The recess can have the shape of a slit, be round, rectangular or assume any other shape that is suitable for the design. The oval recess 7, 7 'has a largest extent which extends across the direction of extension of the expansion part. Row two R2 differs from row one R1 in that row two R2 has a completely oval recess 7 'and two half recesses 7' on each side of the completely oval recess, ie. the rows are arranged in the expansion part so that the recesses 7 in row one R1 are offset relative to the recesses 7 '~ in row two R2. Here the recesses 7 are so offset, see Fig. 3a ', that a line 18, which is substantially parallel to the direction of extension of the expansion part, extends through the center of one of the recesses 7' in row two R2, which line 18 intersects a point 19 located essentially in the middle between two recesses 7 in a row an R1. This placement of the recesses 7, 7 'means that a node 6, 6' is formed between each recess 7, 7 'on each row, see Fig. 3a. By node is meant not only a point but it can also be an area. Point 19 in Fig. 3a 'is the same point as node 6. It can also be seen as follows: the net-shaped pattern 5 of continuous link portions 8 which meet in the nodes 6, 6' is delimited by recesses 7, 7 ', two adjacent recesses 7, 7 'which are arranged at a distance from each other across the direction of extension of the expansion part are arranged at a distance from at least one further recess 7, 7' in the direction of extension of the expansion part, which recesses are evenly displaced relative to each other across the direction of extension of the expansion part. The rows do not have to be offset as described above, but they can be offset more irregularly to each other. Through the above-described placement of the recesses, row one R1 gets three nodes 6 and row two R2 two nodes 6 '.

Fig. 3a "shows how the nodes 6, 6 'in the two rows are connected by link portions 8 of material which together enclose the recesses 7, 7'. A link portion 8 (the dashed area) thus extends from node 6 in a row one R1 to node 6 'in row two R2. The nodes 6, 6' are arranged so that a first imaginary straight line L1 along the link portion 8 extends between the two nodes 6, 6 'which are connected by said link portion. The first line L1 is arranged at an angle till to the direction of extension of the expansion part shown here as the line L. This angle är is suitably as large as possible in order to have as long a link portion 8 as possible. preferably greater than 60 °. As shown in the figures, the same node 6 in row one R1 is also connected to another node 6 'in row two via a link portion 8 (not shown, with the dashed area described above corresponding between the node 6 and the second node 6 ' ). The nodes 6, 6 'are here also arranged to each other so that a second imaginary straight line L2 along the link portion 8 extends between the two nodes 6, 6' which are connected by said link portion 8. The second line L2 is also arranged at an angle 0: 2 to the direction of extension L. of the expansion part Also this angle d; is suitably as large as possible to get as far batch 8 as possible. Preferably the angle on is greater than 45 °, preferably greater than 60 ° The angles on and a; are equally large here. However, they can be of different sizes.

The nodes 6 'in row two R2 are then connected in the same way to the nodes 6 in row three R3, which gives both a third and a fourth imaginary straight line L3, L4 and further imaginary lines which are not shown. The connections continue in the same way over the entire expansion part 3, which gives the expansion part 3 its net-shaped pattern. Here only the node 6 in row one R1 is described which is arranged between the two recesses 7, however, the other two nodes 6 are arranged in a similar manner to the nodes 6 'in row two R2.

The recesses 7, 7 'are, as stated, of oval shape, where the oval shape has its greatest extent across the direction of extension of the expansion part. The location, shape and extent of the recess 7, 7 across the direction of extension L of the expansion part and the angles on, org on the first line L1 and the second line L2 and all the other lines formed over the whole expansion part, which lines each intersect two nodes 6, 6 'which are linked of a link portion 8 determines the appearance of the expansion part 3. If you look at all the rows R1-R11, all the recesses are 7, 7 'and angles or of the same shape and size and with the same distance U í- »SYíšï ílïlïfå than * irl - ~ j. SMQ? G432E§A4_A:.: Qššr: r} tirzf fi tefr 10 15 20 25 30 11 between the recesses 7, 7 'and the recesses 7, 7' in a row are evenly offset against the nearest second row. However, the design of the expansion part 3 and its net-shaped pattern are not limited to this but may vary over the surface of the expansion part 1 in the direction of extension of the expansion part.

The possible force / energy absorption of the expansion part 3 is determined in addition to the design of the expansion part 3 also by the material from which the expansion part 3 is made. Preferably it is of a malleable metal material, also called hardening material. This means that when a point in the structure is loaded and deformed, it will harden and when the material next to it is weaker, it means that the deformation is moved there. Gradually, "all" material becomes involved and thus deformed, which means that it takes a long time before it becomes a location of deformation that can lead to breakage. For example, the stainless material EN 1.4301, AlSl 304 or EN 1.4307, AlSl 304L from the supplier Outo Kumpu or Domex 220 from the company SSAB can be used.

The possible force / energy absorption of the expansion part 3 is also affected by the combination of material thickness, width of the expansion part 3 and the length of the expansion part 3 in the direction of extension of the expansion part and in combination with the number of recesses and the shape of the recesses, the width of the material. extends between two nodes along a link portion 8 in relation to the direction of extension of the expansion part. The expansion part 3 here has a width of about 45 mm and a length of about 70 mm and a thickness of about 3 mm. The oval recesses 7, 7 'here have a width of about 15 mm and a height of about 4 mm.

However, the fastening device is not limited to this.

Figs. 3c and 3d show what the fastening device 1 and its expansion part 3 look like after it has been subjected to a certain force, and thus absorbed the energy that arises. In the coordinate system of Fig. 3d, the direction of extension of the expansion part is ix-direction and the direction across the direction of extension of the expansion part is iy-direction. When the expansion part 3 in Figs. 3a and 3b is subjected to a force which substantially comes in the x-direction and if this force exceeds a predefined value to which the expansion part 3 is adapted, the expansion part will extend the direction of extension (x-direction) of the expansion part. However, this force should be less than the maximum capacity of the fastener. In equipped service vehicles, it is desired that the fastening device 1 be able to withstand expansion of approx. 150 mm before it reaches a force of approx. 7 kN.

However, the fastening device is not limited to this. The fastening device 1 can be dimensioned to withstand higher or lower forces by varying the above-mentioned factors. When the expansion part 3 is subjected to the force which comes mainly in the direction of extension of the expansion part, the link portions 8, which extend between two nodes 6, 6 "will rotate around the nodes 6, 6 'and move in the direction of extension of the expansion part.

If you look at the link portion 8 as described in Fig. 3a "., The node 6 'in row two R2 and the node 6 in row one R1 will move away from each other in the direction of extension of the expansion part. Both nodes are moved in different directions, i.e. the nodes 6, 6 'are moved relative to each other. To understand what is happening, one can examine the event by saying that node 6 in a row an R1 does not move, ie it stays at its starting position. Since the link portion 8 is subjected to a force, the node 6' in row two R2 to be moved upwards (in x-direction) in the direction of extension L of the expansion part, i.e. the imaginary line L1 described previously having an angle oi1 in Fig. 3a "will have a smaller angle (a second angle, angle on in fig. 3d) after the expansion part has expanded.

The node 6 'in row two R2 in Fig. 3d is further away from the node 6 in row 1 R1 iX-joint than it is in Fig. 3a "and closer to the node 6 in Y-joint.

By having long link portions 8 in the expansion element 3, the link portions can move a longer distance in the direction of extension of the expansion part than if one had had short portions. This means that the entire expansion part can be extended a longer distance in the direction of extension of the expansion part. However, the link portions should be adapted so that the expansion element 3 becomes sufficiently stable and does not have any weak points even before the load. The expansion part 3 described above from Figs. 3a, 3b has been pulled out by almost 100% as shown in Fig. 3c.

What happens during the extension is that the material in the link portion 8 deforms when it bends (when the angle changes) and hardens. It works so that when a point / area in the material bends, deforms and hardens and the soft material next to it is engaged, ie. the deformation is moved there and the point / area hardens. Gradually, a || t material in the link portion becomes involved and because the entire net-shaped pattern is connected, the entire expansion element will gradually harden. In this way, the expansion element 3 absorbs the energy that arises during, for example, a collision.

In addition to bending, the link sections will also be stretched later in the process.

The oval recess which extended across the direction of extension of the expansion member in Fig. 3a (before expansion) will now also extend in the direction of extension of the expansion member. The total movement of the node 6 'is also limited by the fact that the same node 6' in row two R2 is connected to another node 6 in row one R1. Thus, the recesses 7 now have the shape of a rectangle, where two opposite corners each point in the direction of extension of the expansion part as shown in Fig. 3d. The width of the expansion part 3 is also affected by the force and the appearance of the mesh-shaped pattern. The width of the expansion part also narrows with the more force it is exposed to, ie. the further it is stretched.

Figs. 4a and 4b show a fastening device 1 with recesses 7 in the expansion part 3 where the recesses are shaped as slits, where the slits extend across the extension direction of the expansion part. The corners of the slots are suitably rounded to avoid obvious fracture boundaries that may form in pointed corners.

The slots 7 are arranged to each other as described above.

Figs. 5a and 5b show a fastening device 1 with recesses 7 in the expansion part 3 where the recesses are shaped as rectangles, where two opposite corners are directed in the direction of extension of the expansion part and where the largest extent of the rectangle, i.e. between the peaks extends across the direction of extension of the expansion member. The corners of the rectangles are suitably rounded to avoid obvious fracture boundaries that can form in pointed corners. The rectangles 7 are arranged to each other as described above. Even when a single embodiment of the invention has been described herein, it will be apparent to those skilled in the art that variations may be made in the construction and the relationship between parts without departing from the scope of the invention as set forth in the appended claims.

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Claims (18)

10 15 20 25 30 14 Claims 1 2.. Fastening device (1) for energy absorption comprising two fastening portions (2) and an expansion part (3), the expansion part (3) having an extension direction between said fastening portions (2) arranged on opposite sides of the expansion part (3), the fastening device (1) is characterized in that the expansion part (3) comprises at least one net-shaped pattern (5) of continuous link portions (8) which meet at nodes (6, 6 '), at least one first imaginary straight line (L1) along a link portion (8) extends between two nodes (6, 6 ') connected by said link portion (8), said line (L1) being arranged at an angle (a1) to the direction of extension of the expansion part. Fastening device (1) according to claim 1, wherein the angle (cx1) between the first line (L1) and the direction of extension of the expansion part is greater than 45 ° and suitably greater than 60 °. 4.. Fastening device (1) according to one of the preceding claims, wherein the expansion part (3), when the fastening device (1) is exposed to and exceeds a predefined force, expands, whereby the nodes (6, 6 ') are moved relative to each other. 5.. Fastening device (1) according to claim 3, wherein said line (L1) moves from its first angle (G1), to a second angle, which second angle is smaller than said first angle (G1) measured from the direction of extension of the expansion part. Fastening device (1) according to one of the preceding claims, wherein the net-shaped pattern (5) of continuous link portions (8) which meet at nodes (6, 6 ') is delimited by limiting portions (7, 7'), preferably in the form of recesses, wherein two adjacent limiting portions (7, 7 ') arranged at a distance from each other across the extension direction of the expansion part are arranged at a distance from at least one further limiting portion (7, 7') in the extension direction of the expansion part, which boundary portions are evenly displaced in relation to each other across the direction of extension of the expansion part. 6.. Fastening device (1) according to one of the preceding claims, wherein the net-shaped pattern (5) of continuous link portions (8) which meet at nodes (6, 6 ') is limited by at least one recess (7, 7'). 7.. Fastening device (1) according to claim 6, wherein at least one of the recesses (7, 7 ') has an oval shape. 8.. Fastening device (1) according to claim 7, wherein the oval recess (7, 7 ') has a largest extent which extends across the direction of extension of the expansion part. 9.. Fastening device (1) according to any one of claims 6-8, wherein at least one of the recesses (7) has a substantially rectangular shape. Fastening device (1) according to claim 9, wherein the rectangular recess (7, 7 ') has a largest extent which extends across the direction of extension of the expansion part. Fastening device (1) according to any one of claims 6-10, wherein at least one of the recesses (7, 7 ') is a slot. Fastening device (1) according to claim 11, wherein the recess (7, 7 ') shaped like a slot has an extension which extends across the direction of extension of the expansion part. i všíläüíjšßfrïfššlåiiiíßâ HH "* f .Jíšärii ål? ë fi ëEiit?" Fastening device (1) according to one of Claims 9 to 12, in which the recesses (7, 7 ') have rounded corners. Fastening device (1) according to one of the preceding claims, wherein the expansion part (3) is flat. Fastening device (1) according to any one of the preceding claims, wherein at least one of said two fastening portions (2) is flat. Fastening device (1) according to one of the preceding claims, wherein at least one of the fastening portions (2) is arranged at an angle to the expansion part (3). Fastening device (1) according to one of the preceding claims, wherein the expansion part (3) and / or at least one of the fastening portions (2) is made of a hardening metallic material. Use of at least one fastening device (1) according to one of the preceding claims for fastening fittings (11) to a wall (14) in a service vehicle (10). '* *' i ^ U bßY fi ïiš-'tfl i-t kal E "2? Q43íÉ94W1fEf> çv-Éifiašictfltæs