FUEL TANK WITH STIFFENING DEVICE

Abstract

The disclosure relates to a fuel tank including a tank wall which has at least two wall sections opposite one another and a stiffening device situated between the two opposite wall sections. The disclosure further relates to a method for manufacturing such a fuel tank. According to the invention, it is provided that the stiffening device includes at least one connecting strut, each end of which has a profile section, which engages with one complementary profile section each on the two opposite wall sections of the container wall in a tension-resistant manner in such a way that the connecting strut absorbs compressive forces acting on the container wall. The method according to the disclosure for manufacturing a fuel tank including a stiffening device of the aforementioned type is characterized by the following steps: shaping the tank from a thermoplastic material in a blow mold, at least two coupling sections being created on opposite wall sections and an opening being created in one of the wall sections; removing the container from the blow mold; manual or mechanical insertion of at least one connecting strut via the opening into an interior of the container, the ends of at least one connecting strut each including a profile section, which may be coupled to one of the coupling sections of the wall sections in a tension-resistant manner; and manual or mechanical coupling of the profile sections of the connecting strut to the coupling sections of the wall sections.

Claims

1. A fuel tank comprising: a container wall having at least two opposite wall sections; and a stiffening device situated between the two opposite wall sections, wherein the stiffening device has at least one connecting strut, each end of which has a strut profile section, which engages with a complementary wall profile section formed unitarily in each on the two opposite wall sections of the container wall in a tension-resistant manner in such a way that the connecting strut absorbs compressive forces acting on the container wall; wherein each strut profile section at the ends of the stiffening device face in a lateral direction such that strut profile sections are connected to the complementary wall profile sections of the container wall by laterally displacing the stiffening device in the lateral direction such that the strut profile sections mate with the complementary wall profile sections.

2. The fuel tank according to claim 1, wherein the complementary wall profile sections of the two opposite wall sections of the tank wall have an undercut area.

3. The fuel tank according to claim 2, wherein the under-cut section is created during a shaping of the opposite wall sections by a shaping element from the outside of the tank.

4. The fuel tank according to claim 3, wherein the tank wall consists of a thermoplastic material and that the shaping element is an insert for a blow mold for manufacturing the container, which is overblown by the respective wall section when the container is blow molded.

5. The fuel tank according to claim 4, wherein the insert has a flat plate section and an insert profile section which is essentially mushroom-shaped in cross section and extends normally to the plate section.

6. The fuel tank according to claim 5, wherein the insert profile section has a height between 20 mm and 120 mm.

7. The fuel tank according to claim 1, wherein the end strut profile sections of the at least one connecting strut include guide elements, which facilitate a pushing of the strut profile sections onto the complementary wall profile sections of the opposite wall sections of the container wall.

8. The fuel tank according to claim 1, wherein the end strut profile sections of the at least one connecting strut include stop elements, which limit a pushing of the strut profile sections onto the complementary wall profile sections of the opposite wall sections of the container wall on one side.

9. The fuel tank according to claim 1, wherein the end strut profile sections of the at least one connecting strut include a detachable securing element, which prevents the removal of the strut profile sections from the complementary wall profile sections of the opposite wall sections of the container wall.

10. The fuel tank according to claim 9, wherein the securing element is designed as a securing bracket, which overlaps, and is configured to be snapped onto, the side sections of the strut profile section.

11. The fuel tank according to claim 1, wherein the at least one connecting strut includes a flat body having a wall thickness of 2 mm to 20 mm extending between the end strut profile sections, which is provided with a plurality of reinforcing ribs extending transversely to its flat side to beyond the strut profile sections.

12. The fuel tank according to claim 1, wherein the tank includes an opening in the area of one of the opposite wall sections, and wherein the complementary wall profile sections are situated near the opening and an opening outline projected onto the opposite wall section.

13. The fuel tank according to claim 12, wherein a distance between the complementary wall profile sections and the opening is less than 100 mm.

14. The fuel tank according to claim 12, wherein a plurality of connecting struts are situated at equal or unequal angular distances from one another around the opening.

15. The fuel tank according to claim 12, wherein a distance between the complementary profile sections and the opening is less than 50 mm.

16. A method of forming a fuel tank comprising: providing a stiffening device having at least one connecting strut, each end of which has a strut profile section; positioning a parison within a mold having at least two inserts formed as a shaping element; blow molding the parison to define a container wall for the fuel tank having two opposite wall sections defining complementary wall profile sections formed by overblowing the parison around the insert, the complementary wall profile sections having and undercut area; inserting the stiffening device through an opening in the container wall and laterally displacing the stiffening device such that the strut profile sections engage and mate with the complementary wall profile sections in a tension-resistant manner in such a way that the connecting strut absorbs compressive forces acting on the container wall.

17. The method according to claim 16, wherein the insert has a flat plate section and an insert profile section which is essentially mushroom-shaped in cross section and extends normally to the plate section.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] The disclosure is explained in greater detail below with reference to an exemplary embodiment schematically shown in the drawing. Herein:

[0020] FIGS. 1a through c show a cross section and top and bottom views of a fuel tank with a stiffening device;

[0021] FIG. 2 shows a cross section of the fastening point of a connecting strut on the container wall;

[0022] FIG. 3 shows a cross section of the container in the area of a container opening for explaining the installation process of the connecting strut;

[0023] FIGS. 4a and b show two variants of a secure fastening of the connection strut to the container wall;

[0024] FIGS. 5a through c show detailed views of a profile section of the connecting strut;

[0025] FIGS. 6a through c show a variant of a securing element for the connecting strut; and

[0026] FIGS. 7a through d show different views of an insert for a blow mold to create a complementary profile section on the container wall.

DETAILED DESCRIPTION

[0027] The fuel tank 10 shown in FIG. 1 includes an opening 12 on top in its installed position in its tank wall 14, which is primarily intended for mounting an essentially pot-like fuel delivery module, not further depicted. Three connecting struts 16 extending between an upper and a lower wall section, which stiffen the container 10 and thereby absorb compressive forces acting on the container wall 14 from the inside or outside, are situated around the circumferential surface of the cylindrical projection of the opening 12 on the container bottom.

[0028] FIG. 2 shows a detailed view of the fastening area of the connecting strut 16 on the container wall 14. For this purpose, the connecting strut 16 has a profile section 18 at each of its end areas, which overlaps a complementary profile section 20 of the container wall 14. Depending on the application requirement, the profile sections 18 may be similar in design or may have different dimensions. The complementary profile section 20 of the container wall 14 is produced by an insert 40, which has been arranged in a blow mold prior to the shaping of the container 10 in the blow mold, and is then partially enclosed by the wall material during the shaping of the container contours.

[0029] FIG. 3 shows a cross section of the container 10 in the area of the opening 12. The connecting strut 16, for mounting the same, is inserted into the container through the opening 12 into the interior of the container 10 (arrow 22) and then laterally displaced (arrow 24) in such a way that the profile section 18 of the connecting strut 16 is pushed onto and overlaps the complementary profile section 20 of the container wall 14. Due to the positive connection between the profile section 18 of the connecting strut 16 and the complementary profile section 20 of the container wall 14, forces 14 acting from inside or outside on the container wall as tensile forces and compressive forces in the longitudinal direction of the connecting strut 16, i.e., in the connecting direction between the opposite wall sections of the container wall 14 supporting the complementary profile sections 20, may be absorbed by the connecting strut 16. To better absorb pressure forces acting on the connecting strut 16, the profile section 18 includes widened foot sections 26 (FIG. 2), which may be supported on the inside of the container wall 14.

[0030] FIG. 4 shows two possibilities for securing the connecting strut 16 against undesirable detachment from the complementary profile section 20. In FIG. 4a, the complementary profile sections 20 of the container wall 14 are situated in the immediate vicinity of a fuel delivery module installed in the container 10 after the mounting of the connecting strut 16, the circumferential surface of which is represented by the broken line 28. Due to the proximity of the connecting strut 16 to the fuel delivery module, a displacement of the connecting strut 16 in the direction of the latter is blocked and the fastening of the connecting strut 16 is thereby secured. To remove the connecting strut 16, the fuel delivery module would first have to be removed from the container 10, which would be necessary in any case for accessing the connecting strut 16. In the variant of FIG. 4b, the profile section 18 of the connecting strut 16 includes a leaf spring 30, which rests against a rear edge 32 of the complementary profile section 20 when the profile section 18 of the connecting strut 16 is pushed completely onto the complementary profile section 20 of the container wall 14.

[0031] FIG. 5 shows detailed views of the profile section 18 of the connecting strut 16. FIG. 5a shows the profile section 18 of the connecting strut 16 mounted on the complementary profile section 20 of the container wall 14. Positioning when the profile section 18 is pushed onto the complementary profile section 20 is facilitated by a leading bevel edge 34. A stop 36 is provided opposite the leading bevel edge at the other end of the profile opening, which prevents the profile section 18 from being pushed over the complementary profile section 20 beyond the desired final assembly position. The connecting strut 16 is designed essentially as a flat body extending between the end profile sections 18. In order to be able to better absorb pressure forces in particular, the connecting strut 16 includes a plurality of stiffening ribs 38, which expediently extend over the entire length of the connecting strut 16, i.e., also cover the area of the profile section 18.

[0032] FIG. 6 shows the area of the profile section 18 of the connecting strut 16 in different views. A securing element for the connecting strut 16 is provided that is designed as a securing bracket 50. The securing bracket 50 overlaps the profile opening of the profile section 18 and has two lateral snap-in openings 52. Once the connecting strut 16 is installed, the securing bracket is snapped onto complementary locking lugs 54 on the side surfaces of the profile section 18.

[0033] FIG. 7 shows various views of the insert 40. The insert 40 has a flat plate section 42 and a profile shaping section 44 projecting essentially vertically therefrom, which is approximately mushroom-shaped in cross section, in order in this way to facilitate the shaping of the undercut section of the complementary profile section 20. Openings 46, which ensure an additional positive connection when the insert 40 is overmolded by the material of the container wall 14, are provided in a web-like connection area between the profile shaping section 44 and the plate section 42.

[0034] In summary the following may be noted: The disclosure relates to a fuel tank 10 including a container wall 14 having at least two opposite wall sections and a stiffening device situated between the two opposite wall sections. The disclosure further relates to a method for manufacturing such a fuel tank. According to the invention, it is provided that the stiffening device includes at least one connecting strut 16, each end having a profile section 18, each of which has a complementary profile section 20 that engages on the two opposite wall sections of the container wall 14 in a tension-resistant manner in such a way that the connecting strut 16 absorbs compressive forces acting on the container wall 14. The method according to the disclosure for manufacturing a fuel tank 10 including a stiffening device of the aforementioned type is characterized by the following steps: shaping the container 10 from a thermoplastic material in a blow mold, wherein at least two coupling sections are created on opposite wall sections and an opening 12 is created in one of the wall parts; removing the container 10 from the blow mold; manual or mechanical insertion of at least one connecting strut 16 via the opening 12 into an interior of the container 10, the at least one connecting strut 16 having a profile section 18 at each end, which can be coupled with one of the coupling sections of the wall sections in a tension-resistant manner; and manual or mechanical coupling of the profile sections 18 of the connecting strut 16 to the coupling sections of the wall sections.