DE102018129469A1 - Double-walled envelope structure for a car body - Google Patents

Abstract

The invention relates to an envelope structure (1) for a car body of a rail vehicle, with at least one envelope profile (2), with an inner wall (3), an outer wall (4), a stiffening element (6) stiffening the envelope structure (1) at least in sections is inserted between the outer wall (4) and inner wall (3) in a form-fitting manner.

Description

The invention relates to an envelope structure for a car body for a vehicle, and to a method for producing an envelope structure.

Envelope structures of car bodies are often formed from double-layer structures such as double-walled extruded aluminum profiles. Such an envelope structure shows, for example DE 10 2011 088 509 B4 . The double-walled structure of aluminum car bodies is used to produce sufficient strength while at the same time being lightweight. For this purpose, the outer and inner walls of the extruded aluminum profiles are usually connected to one another via struts which transmit forces introduced into the shell structure or distribute them to the outer and inner walls.

The envelope profiles are produced in the required length using the extrusion process and then placed on top of one another and welded together to produce the envelope structure, that is to say car body floors, walls and ceilings. Due to the double-walled design of the extruded aluminum profiles, it is necessary that both the outer and the inner walls of the stacked cladding profiles are connected to each other in a force-conducting manner. This can be achieved by means of weld seams which are applied both from the outside and from the inside of the car body during the manufacture of the car body, or by means of adhesive connections, as in the DE 10 2011 088 509 B4 described.

Cut-outs in the car body, which are provided for windows and doors, for example, reduce the rigidity of the car body. In order to compensate for the associated lower strength, the wall thicknesses of the envelope profiles used can be increased. In the production by extrusion, the cross sections are usually the same. The wall thickness can therefore only be changed over the entire length of an envelope profile. However, this leads to increased material expenditure and thus weight of the car body. Alternatively, additional supporting components can be welded on in order to increase the rigidity, as a result of which the effort for producing the car body is significantly greater.

The invention is therefore based on the object of creating an easily and inexpensively producible envelope structure which has a low strength and high strength.

This object is achieved according to the invention with an envelope structure according to claim 1. Furthermore, the object is achieved with a rail vehicle according to claim 13 and a use of the device according to claim 15. Advantageous embodiments of the invention are contained in the subclaims.

According to the invention, the object is achieved in that the envelope structure has at least one envelope profile with an inner wall and an outer wall, a stiffening element stiffening the envelope structure at least in sections being provided, which is introduced in a form-fitting manner between the outer wall and the inner wall.

The invention thus makes it possible to use envelope profiles with smaller wall thicknesses and still achieve sufficient strength. The higher strength is achieved through the support effect of the stiffening element used. The stiffening element enables a more direct power transmission between the inner and outer wall and supports them against each other.

The term envelope structure denotes the structure of the outer shell of a rail vehicle. This can include car body floors, walls and / or ceilings and be formed by one or more envelope profiles. The shell structure can have the actual outer shell, structural elements such as struts and / or an inner shell.

The envelope profile can be formed from a plurality of extruded profiles which are welded together. The welding process preferably takes place before the stiffening element is inserted.

According to a preferred embodiment of the invention, supporting forces acting between the stiffening element and the at least one envelope profile can be transmitted essentially in a form-fitting manner during operation. For this purpose, the stiffening element can have contact surfaces which rest on adjacent surfaces of the envelope profile. The stiffening element can rest on at least four, preferably five, most preferably seven support surfaces on the envelope profile. The stiffening element preferably extends in regions of the envelope profile in which relatively large forces or moments occur.

In a preferred variant of the invention, the stiffening element bears against the inner wall or the outer wall of the envelope profile. According to an expedient development of the invention, the stiffening element can rest on the inner wall and on the outer wall. This enables direct power transmission between the inner and outer wall.

In a further variant, the stiffening element can have at least two force transmission surfaces, which are arranged on essentially opposite sides of the stiffening element. The stiffening element can be designed for insertion into a receiving space in the envelope structure, the receiving space being in contact with a plurality of surfaces when the stiffening element is inserted. The envelope structure can be formed by extruded profiles. Accordingly, the receiving space can be formed by one or more, in particular double-walled extruded profiles.

According to a further variant of the invention, at least three force transmission surfaces can be provided. The three force transmission surfaces can each run essentially orthogonally to a common force action plane in order to be able to absorb forces and moments from different directions, which essentially lie on a common force action plane. The force action plane ideally runs parallel or tangential to the outer shell of the shell structure. The force action level is therefore a level that is spanned by force vectors acting in the envelope structure.

In a further expedient development, the stiffening element can have at least one receptacle for a strut which reinforces the outer shell of the car body and the receptacle can comprise at least one force transmission surface on its inside in order to enable force transmission in further directions.

At least one strut connecting the inner wall and the outer wall can be provided in the enveloping profile, the stiffening element abutting or engaging around the strut. The strut can thus serve as a further form-fitting means that reinforces the form-fitting with the envelope profile. In particular, a displacement of the stiffening element in the envelope profile can be blocked by the further positive locking.

In an expedient development of the invention, at least two struts are provided, which rest on opposite sides of the stiffening element. In this way, the stiffening element can be positively secured against displacement in two directions.

One or both struts can engage in or be surrounded by the stiffening element in order to optimize the form fit between the stiffening element and the envelope profile. Thus, tensile forces or bending moments can also be transmitted via the stiffening element.

Ideally, the struts run parallel to one another, so that the stiffening element can be inserted into the envelope profile in an insertion direction. The direction of insertion can correspond to an extrusion direction of the envelope profile.

The struts can preferably run continuously from the inner wall to the outer wall. In addition, the struts ideally run in an extrusion direction, the direction of insertion corresponding to the extrusion direction.

In a further embodiment of the invention, at least three struts can be provided, each abutting one side of the stiffening element and / or engaging in the stiffening element. Forces can thus be transmitted on more than two levels.

According to a preferred variant of an envelope structure according to the invention, the stiffening element is formed from a composite material (composite, aluminum foam ...). The stiffening element can in particular be formed from a fiber composite material, such as a carbon fiber or a glass fiber composite material. This enables high strength with low weight. Alternatively, the stiffening element can be formed from aluminum, in particular from foamed aluminum.

The stiffening element can be designed so that it can be molded into the envelope profile. In a non-hardened state, the stiffening element can have slightly larger dimensions than a receiving space provided for receiving the stiffening element between the inner and outer walls. When the stiffening element is inserted, it can be slightly compressed in order to achieve a complete positive connection between the stiffening element and the envelope profile in the hardened state.

The envelope structure can have a cutout. The cutout can be provided in a side wall area, an end wall area, a roof area and / or a floor area. The cutout can in particular be a door cutout and / or a window cutout and / or a cutout for an air conditioning system. The stiffening element can adjoin the cutout. In this way, the envelope structure is stiffened, in particular in the edge region of the cutouts, and deformations of the envelope structure are blocked.

In a further embodiment of the invention, the stiffening element can border or limit the cutout at least in sections. The stiffening element can have a frame of the cutout, at least in sections form, especially a window frame. In further configurations, the stiffening element can form a door frame. The stiffening element can be used on bushings in the envelope structure, for example on a bushing for an air duct. The stiffening element can form sealing surfaces on bushings in order to ensure the best possible sealing of the car body.

A filler material can be provided between the stiffening element and the enveloping profile in order to close gaps between the enveloping profile and the stiffening element or to smooth unevenness on the contact surfaces. The filling material is ideally incompressible in a hardened state. The filling material can be formed at least partially by a thermoset and / or quartz sand.

According to a further variant of the invention, the stiffening element can be adhesively connected to the inner wall, outer wall or the strut. An adhesive can be used to connect the stiffening element to the envelope profile. Alternatively, in the case of a stiffening element made of a composite material, the matrix material can serve as an adhesive. For example, the material of the stiffening element can comprise a thermoset which only hardens when the stiffening element is inserted into the envelope profile and connects it to the envelope profile.

In a car body with an envelope structure according to the invention, this can form a side wall, a roof and / or a floor of the car body.

According to a method for producing an envelope structure according to the invention, an envelope section is first formed from envelope profiles. Several envelope profiles can be connected to one another, in particular welded, in order to form the envelope section. A stiffening element can then be inserted into a receiving space of the envelope section. The stiffening element can preferably be inserted into the envelope section in the extrusion direction.

Remaining spaces, such as gaps between the stiffening element and the covering section, can be filled with a filling material during the insertion of the stiffening element. For this purpose, the stiffening element can be provided or coated with filling material before insertion. Alternatively, gaps can be filled with a filling material after the stiffening element has been inserted.

In a further variant of the method according to the invention, the stiffening element can be glued into the receiving space in order to be able to additionally transmit forces via an adhesive connection. Filling with filling material and gluing can be done at the same time by using the filling material as an adhesive. The filling material can be formed from a thermoset. The filler material may contain an incompressible filler such as e.g. Quartz sand.

Figure list

• 1 einen Ausschnitt einer Hüllstruktur für ein Schienenfahrzeug;
• 2 eine Schnittansicht gemäß der Stelle A-A der Hüllstruktur der 1;
• 3 eine Schnittansicht gemäß der Stelle B-B der 2;
• 4 eine Perspektivansicht des in 3 gezeigten Ausschnittes der Hüllstruktur.

The accompanying drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. Show it:

• 1 a section of an envelope structure for a rail vehicle;
• 2nd a sectional view according to the location AA the envelope structure of the 1 ;
• 3rd a sectional view according to the location BB the 2nd ;
• 4th a perspective view of the in 3rd shown section of the envelope structure.

The following is with reference to the 1 to 4th a preferred embodiment of the envelope structure according to the invention is described.

1 shows a section of an envelope structure 1 that forms a side wall of a rail vehicle. The envelope structure 1 can be formed by a large number of envelope profiles, which are partially placed on top of one another in a form-fitting manner and welded to one another on their inner and / or outer sides. The envelope structure 1 is part of a car body for a passenger vehicle. The envelope structure shows accordingly 1 Cutouts 10th , 11 , 12 , 13 that serve to create accesses and windows. The cutouts 11 , 12 , 13 form windows of the car body, the cutout 10th an access.

In the area of the cutouts 10th , 11 , 12 , 13 is the flow of force in the envelope structure 1 disturbed. Especially in the corner areas of the cutouts 10th , 11 , 12 , 13 This creates increased tensions and the special strength requirements for the shell structure 1 put. In the in the 1 to 4th described embodiment, therefore, a stiffening element is provided in the corner areas.

In the sectional view of the 2nd is a cross section of the envelope structure 1 at the point AA the 1 shown. The envelope structure 1 is of an envelope profile 2nd educated. The envelope profile 2nd has inner wall 3rd and an outer wall 4th on. Between the inner wall 3rd and the outer wall 4th run struts 5 , 7 , 9 which the inner wall 3rd and the outer wall 4th connect and support each other. At the same time, the struts form 5 , 7 , 9 a recording room 14 . All striving 5 , 7 , 9 are in an extrusion process to produce the envelope profile 2nd originated and extend correspondingly in an extrusion direction S .

Between the inner wall 3rd and outer wall 4th is a stiffening element 6 used that in the recording room 14 form-fitting from the inside wall 3rd and outer wall 4th as well as the struts 7 , 9 is held. According to the course of the adjacent struts 7 , 9 is the stiffening element 6 in the recording room 14 used. The stiffening element 6 will be in an insertion direction E in the recording room 14 inserted in the direction of extrusion S corresponds.

3rd shows a sectional side view of the section of FIG 2nd . The stiffening element 6 borders on the neckline 12 at. The on the neckline 12 adjacent surface of the stiffening element 6 follows the course of the section 12 or the cutout 12 adjacent surface of the stiffening element 6 aligns with the edge of the neckline 12 .

The stiffening element 6 has contact surfaces 16 , 17th on which the stiffening element 6 on struts 7 , 9 lies on. The contact surfaces 16 , 17th run parallel to the flanks of the struts 7 , 9 and thus offer the possibility of a flat power transmission. The stiffening element 6 lies on its top with the contact surface 17th on the strut 7 on, on its underside with the contact surface 16 on the strut 9 . Between the two struts 7 and 9 a transmission of moments is possible.

On one of the cutouts 12 opposite side of the recording room 14 is another strut 8th provided which like the other struts 7 , 9 in the extrusion direction S runs and the inner wall 3rd connects to the outer wall (not shown here). The stiffening element 6 is with a slit 15 provided in the strut 8th is included. The slot 15 ideally adjoins the strut on both sides 8th at. Thus the strut 8th from the stiffening element 6 embraced or the strut 8th engages in the stiffening element 6 a. As a result, tensile forces can extend transversely to the extension of the strut 8th be transferred via the form fit. Torques can also be transmitted, in particular in a direction perpendicular to the direction of insertion E trending direction. Through the strut 8th is the form fit between the stiffening element 6 and the envelope structure 1 or the envelope profile 2nd added.

4th shows the section of the envelope structure 1 according to 2nd and 3rd in a perspective view. The width of the stiffening element 6 corresponds approximately to the width of the recording room 14 , the stiffening element 6 is therefore directly on the inside of the inner wall 3rd as well as on the inside of the outer wall 4th at. The recording room goes up 14 through the strut 7 limited, down by the strut 9 . The strut 8th forms a stop in the direction of insertion E . It limits movement of the stiffening element 6 in the direction of insertion E and thus simplifies the assembly of the stiffening element 6 .

Contrary to the direction of insertion E , towards the neckline 12 , has the stiffening element 6 the contour of the cutout 12 on. The inner wall 3rd and the outer wall 4th are thus seamlessly supported against each other in this area. The stiffening element 6 also forms a window frame in sections.

The specific embodiments described and illustrated are not binding for the implementation of the invention, but can be suitably modified within the scope of the present invention without departing from the scope of the present invention.

Reference symbol list

E

Direction of insertion

S

Extrusion direction

1

Envelope structure

2nd

Envelope profile

3rd

Interior wall

4th

Outer wall

5

strut

6

Stiffening element

7, 8, 9

Strive

10, 11, 12, 13

Neckline

14

Recording room

15

slot

16.17

Contact surface

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102011088509 B4 [0002, 0003]

Claims (14)

Envelope structure (1) for a car body of a rail vehicle, with at least one envelope profile (2), with an inner wall (3), an outer wall (4), a stiffening element (6) stiffening the envelope structure (1) at least in sections being provided, which has a positive fit is introduced between the outer wall (4) and inner wall (3). Envelope structure (1) Claim 1 , In operation, supporting forces acting between the stiffening element (6) and the at least one envelope profile (2) can be transmitted essentially in a form-fitting manner. Envelope structure (1) according to one of the above claims, wherein the stiffening element (6) abuts the inner wall (3) and / or the outer wall (4). Envelope structure (1) according to one of the above claims, wherein at least one strut (5, 7, 8, 9) connecting the inner wall (3) and the outer wall (4) is provided and the stiffening element (6) on the strut (5, 7 , 8, 9) is present or engages around it. Envelope structure (1) according to one of the above claims, wherein at least two struts (5, 7, 8, 9) are provided which rest on opposite sides of the stiffening element (6). Envelope structure (1) according to one of the above claims, wherein at least three struts (5, 7, 8, 9) are provided, each abutting one side of the stiffening element (6) and / or engaging in the stiffening element (6). At least three bars to absorb tensile forces. Envelope structure (1) according to one of the above claims, wherein the stiffening element (6) is formed from a composite material (composite, aluminum foam ...). Envelope structure (1) according to one of the above claims, wherein the envelope structure (1) has a cutout (10, 11, 12, 13), in particular a door cutout (10) and / or a window cutout (11, 12, 13) and / or a cutout for an air conditioning system, and the stiffening element (6) adjoins the cutout (10, 11, 12, 13). Envelope structure (1) according to one of the above claims, wherein the stiffening element (6) surrounds the cutout (10, 11, 12, 13) at least in sections. Envelope structure (1) according to one of the above claims, wherein the stiffening element (6) is adhesively connected to the inner wall (3), outer wall (4) or the strut (5, 7, 8, 9). Car body for a rail vehicle, characterized by an envelope structure (1) according to one of the above claims. Body according to Claim 11 , wherein the envelope structure (1) forms a side wall, a roof or a floor of the car body. Method for producing an envelope structure (1) according to one of the Claims 1 to 10th , characterized by the steps: a. Producing an envelope section from envelope profiles, b. Then inserting a stiffening element into a cavity of the envelope section. Procedure according to Claim 13 , characterized in that the stiffening element is glued into the cavity.

Images