DE19806761A1 - Seat bowl for vehicle seat - Google Patents

Abstract

The seat bowl (or other component, e.g. the inner sheet of a tailgate or hood) is produced by super-plastic forming (SPF) from a nonferrous metal alloy such as an aluminum alloy containing magnesium or a magnesium alloy containing aluminum. A semifinished sheet product (13), e.g. a thin sheet of 0.5-3 mm in thickness, forms the basis for the manufacture.

Description

The present invention relates to a motor vehicle part, in particular a seat shell Motor vehicle seat or a body part (e.g. a rear lid inner panel or a Engine compartment lid inner panel or a door inner panel) of a motor vehicle, and a Process for its manufacture.

Motor vehicle parts are predominantly by deep drawing, stamping, bending and / or Roll processes made. They mainly consist of steel; lately come too reinforces parts made of aluminum, magnesium or plastics.

In the field of aerospace, superplastic forming (superplastic forming, also called SPF for short) is used as a further forming process for metallic materials. Superplasticity is a hot-forming behavior, which is understood to mean the ability of a metallic material to withstand very low yield stresses without constriction and practically without strain hardening. It can withstand degrees of deformation from a few 100% to over 1000% without failing due to tearing. A characteristic of the superplastic behavior of materials is the strong dependence of the yield stress on the strain rate. Superplastic materials are characterized microscopically by a very fine-grained structure with grain sizes of a few micrometers. The superplastic forming temperature t _U (specified in K) is greater than half the melting temperature t _S (also specified in K) of the superplastic material: t _U <0.5. t _p .

Superplastic forming processes and components made from them are e.g. B. known from the publications DE 197 14 631 A1, JP 05 059 568 A, DE 197 00 320 A1, JP 06 049 576 A, DE 38 26 636 A1, JP 08 269 589 A and DE 42 41 421 A1.

It is the task of the state of the art of the production of motor vehicle parts initially mentioned type and to further develop the motor vehicle parts produced in this way.

This is achieved by a method for manufacturing a motor vehicle part according to claim 1 and its developments and by a motor vehicle part according to claim 21 and its further training solved.

The process of superplastic forming enables the previous limits of the Forming of metallic materials - namely the relatively high yield stress due to the limited resilience - to overcome. The super plastic Semi-finished workpieces to be formed can be produced in a single manufacturing step to be produced with final dimensions. Elaborate post-processing, machining or As a result, joining processes can generally be dispensed with. The one with the superplastic Forming surfaces obtained are very smooth and dense, hence of very high quality.

Due to the limited forming speed compared to deep drawing superplastic forming is superplastic forming especially for the Prototype and small series construction interesting. But it is also used in mass production quite possible.

In motor vehicle construction, in particular motor vehicle body construction, is for reasons of Weight reduction in lightweight construction (taking the necessary into account, of course) static and dynamic strengths). In addition to aluminum Magnesium alloys are also used to an increasing extent. Show however Magnesium and its alloys are only one because of their hexagonal lattice limited cold formability. Given this, the combination of Magnesium and magnesium alloys with superplastic forming make sense as one thereby avoiding their limited cold formability.

Compared to "normal plastic" materials, it deforms in a super plastic The entire structure of the superplastic forming process is homogeneous and evenly. There is no springback after the deformation.  

A crucial feature of superplastic materials is a very fine-grained structure with grain sizes of a few micrometers, in particular 1 to 10 micrometers. From this it can be seen that superplasticity is linked to the existence of grain or phase boundaries. In the case of superplastic forming, there is no significant change in grain shape, but rather the preservation of coaxiality as well as grain rotation and change of neighbor (instead of grain stretching in the direction of tension as with normal plastic deformation) occurs. The superplastic forming takes place above the recrystallization temperature of the superplastic material; this is generally half the melting temperature t _S (given in K) of the material.

Certain have proven to be particularly suitable for superplastic forming Magnesium-containing aluminum alloys or certain aluminum-containing ones Magnesium alloys proven. Alloys with low Iron content preferred, which should preferably be less than 0.004 wt .-%. As Initial semi-finished products for the superplastic forming of seat shells by Motor vehicle seats or body parts of motor vehicle parts (e.g. trunk lid Inner sheets, engine compartment lid inner sheets or door inner sheets) serve in the general sheet metal semi-finished products, in particular sheet metal semi-finished products with a thickness between 0.5 and 3 mm.

The invention is described in the following using an exemplary embodiment which is in several Variants is demonstrated, explained in more detail. The attached drawing shows:

Fig. 1 shows a schematic cross section through an embodiment of an apparatus for performing the method for manufacturing a motor vehicle part.

The device, generally designated 1 , which is drawn schematically in cross section in FIG. 1, is used to manufacture a motor vehicle part from a metallic semi-finished product 13 a by superplastic forming (also called SPF for short). The SPF device 1 comprises a heat-insulating frame 2 which can be opened for inserting the semifinished product 13 a and for removing the motor vehicle part, as is known from devices for producing aerospace components (therefore not shown in more detail in FIG. 1). .

Within the heat-insulating frame 2 there is a heat-insulating lower support part 3 a, above which a lower electrically operated heating plate 4 a is arranged. On the lower heating plate 4 a rests in thermally conductive contact a die 8 , which represents the negative shape of the body part to be produced. On a seal 11 , which is arranged circumferentially on the edge of the die, the semi-finished product 13 a is made of a 1.6 mm thick sheet metal.

A molded upper part 18 is located above the sheet metal semifinished product 13 . The upper mold part 18 is connected via a flexible SPF-gas inlet pipe 7, which is driven by means of a gas inlet controller 14 SPF using an SPF gas inlet. 6

The upper mold part 18 is attached in heat-conducting contact on the underside of an electrically operated upper heating plate 4 b, which in turn is attached to the underside of a heat-insulating upper support part 3 b. The upper mold part 18 , the upper heating plate 4 b and the upper support part 3 b can be moved vertically up and down by means of a pressure stamp 12 . Accordingly, the SPF gas inlet line 7 is designed to be flexible. The pressure stamp 12 produces the mechanical mold locking pressure against the gas pressure acting during superplastic forming and prevents the upper mold part 18 from being lifted off from the sheet metal semifinished product 13 during superplastic forming.

The sheet metal semifinished product 13 shown in FIG. 1 consists of AZ 31 , an aluminum-containing magnesium alloy with the composition 3% by weight aluminum Al, 0.7% by weight zinc Zn, 0.2% by weight manganese Mn, the rest magnesium Mg as well usual impurities. In addition, for example, the following aluminum or magnesium alloys are also suitable as materials for the semifinished product 13 a:
AZ 61: composition 6% by weight aluminum Al, 0.7% by weight zinc Zn, 0.17% by weight manganese Mn, balance magnesium Mg as well as usual impurities;
AZ 91: composition 90.15% by weight of magnesium Mg, 9% by weight of aluminum Al, 0.15% by weight of manganese Mn, 0.7% by weight of zinc Zn and also conventional impurities;
AlCu6: composition 0.5% by weight of zirconium Zr, 6% by weight of copper Cu, remainder aluminum Al and usual impurities;
Ma21: composition 80.4% by weight of magnesium Mg, 5.2% by weight of aluminum Al, 4.7% by weight of cadmium Cd, 8.1% by weight of lithium Li, 0.2% by weight Manganese Mn, 1.4% by weight zinc Zn as well as usual impurities;
a magnesium alloy of the composition 1.6% by weight cadmium Cd, 3.1% by weight zinc Zn, 0.65% by weight zirconium Zr. 0.95% by weight of lanthanum La, the remainder being magnesium Mg and usual impurities;
a magnesium alloy of the composition 1.86% by weight aluminum Al, 0.79% by weight zinc Zn, 0.053% by weight manganese Mn, 0.001% by weight iron Fe, balance magnesium Mg and usual impurities;
a magnesium alloy of the composition 8.5% by weight lithium Li, balance magnesium Mg and usual impurities;
a magnesium alloy with the composition 1.5% by weight of manganese Mn, 3% by weight of Cer Ce, the remainder being Magnesium Mg and usual impurities;
ZK 60: composition 6% by weight of zinc Zn, 0.5% by weight of zirconium Zr, balance magnesium Mg as well as usual impurities;
ZW 3: composition 3% by weight zinc Zn, traces of yttrium Y, remainder magnesium Mg and usual impurities;
MgAl12: composition 12% by weight aluminum Al, balance magnesium Mg as well as usual impurities;
AC 120 (AlMg0.4Si1.2Mn): composition 0.4% by weight of magnesium Mg, 1.2% by weight of silicon Si, traces of manganese Mn, remainder aluminum Al as well as usual impurities.

A superplastic forming process for the manufacture of a motor vehicle part, e.g. B. a seat shell of a motor vehicle seat or a body part (z. B. a trunk lid inner panel or an engine compartment lid inner panel or a door inner panel) runs in the device 1 approximately as follows:

First, the device 1 is opened in order to insert the sheet metal semifinished product 13 into the device 1 . The sheet metal semifinished product 13 is arranged on the edge of the circumferential seal 11 on the die 8 . Alternatively, the die 8 can also be removed from the device 1 , the semifinished product 13 a can be arranged outside the device 1 on the die 8 , and both can then be reinserted into the device 1 . The device 1 is then closed again. This state is shown in FIG. 1.

Then (indicated by arrow 19 in Fig. 1) the pressure stamp 12 with the upper heat-insulating support part 3 b, the upper heating plate 4 b and the upper mold part 18 move downward until the upper mold part 18 is pressed onto the semi-finished product 13 a . The upper mold part 18 , the semifinished product 13 a, the seal 11 and the die 8 then contain two gas spaces which are separate from the surroundings, namely a lower gas space 20 between the sheet metal semifinished product 13 and the die 8 and an upper gas space 21 between the die 8 and the upper mold part 18 . From the SPF gas inlet 6 - controlled by the SPF gas inlet control 14 - a compressed gas is admitted into the upper gas space 21 through the SPF gas inlet line 7 , which exerts a compressive force on the sheet metal semifinished product 13 in the direction of the female mold 8 . By means of the electrically heated heating plates 4 a, 4 b (which in other embodiment variants of the device 1 can also be heated, for example, by heated oil flowing through them), the sheet metal semi-finished product has in the meantime been heated to its forming temperature. The superplastic forming process now begins, in which the semifinished sheet metal product 13 bears against the negative form of the die 8 in order to form the positive form of the body part to be produced.

Then the upper gas chamber 21 is relieved of pressure, the pressure stamp 12 with the upper support part 3 b, the upper heating plate 4 b and the upper mold part 18 moves upward, and the molded body part can (alone or together with the die 8 ) for cooling from the device 1 can be removed. The device 1 can then with the next sheet metal 13 , the z. B. in the meantime may already have been arranged ready prepared on a second, different die 8 outside the device 1 .

For aluminum parts, the forming speed is generally 10 ^-3 s ^-1 to 10 ^-4 s ^-1 . The SPF gas pressure for superplastic forming is preferably controlled over time during the forming process in order to ensure a defined forming tension during the entire forming process. In the manufacture of an inner panel of a tailgate from the magnesium-containing aluminum alloy AZ 31, the SPF gas pressure was used for superplastic forming during the forming process, e.g. B. regulated between 5 bar and 40 bar. A noble gas (e.g. argon) or a mixture of noble gases is preferably used as the SPF compressed gas. In the case of semi-finished products made of magnesium alloys in particular, the use of noble gases or noble gas mixtures can prevent excessive oxidation of the sensitive surface at the elevated temperature of the SPF forming process.

Particularly in the superplastic forming of aluminum semi-finished products, it has been found that it is advantageous, on the back side 17 of the semi-finished product 13 a (ie, on which the SPF gas pressure exposed side 16 opposite side 17 of the semi-finished product 13 a) a regulated counterpressure to be provided in order to avoid locally excessive strains ("sink marks"). For this purpose, the device 1 is equipped with a back pressure gas inlet line 10 controlled by a back pressure gas inlet control 15 , via which the lower gas space 20 can also be pressurized by a back pressure gas inlet 9 from a back pressure gas inlet.

The forming temperature of the already mentioned trunk lid inner sheet from AZ 31 was approximately 425 to 525 ° C, preferably approximately 450 to 500 ° C, in particular approximately 475 ° C. Cycle times of about 15 minutes were achieved, of which about 7 to 10 minutes were for the actual forming time and the rest for loading and unloading the device 1 .

The rear lid inner panel produced in this way is manufactured to the final dimensions due to the superplastic forming; if necessary, only protruding edge regions have to be separated by simple cutting processes. The surface quality achieved is very good; A very dense, smooth and homogeneous surface results in particular on the pressure side 16 which is subjected to SPF gas pressure. The motor vehicle parts produced can be easily treated, e.g. B. painted like conventional magnesium castings. The motor vehicle parts produced by superplastic forming can also be KTL-coated and / or powder-coated.

Reference list

1

SPF device

2nd

heat-insulating frame

3rd

a,

3rd

b heat-insulating supporting parts

4th

a,

4th

b heating plates

6

SPF gas inlet

7

SPF gas inlet pipe

8th

die

9

Back pressure gas inlet

10th

Back pressure gas inlet line

11

seal

12th

Pressure stamp

13

Semi-finished sheet metal

13

a semi-finished product

14

SPF gas inlet control

15

Back pressure gas inlet control

16

Printed page

17th

back

18th

Molded top

19th

arrow

20th

lower gas space

21

upper gas space

Claims (32)

1. A method for producing a motor vehicle part, characterized in that the motor vehicle part is produced by superplastic forming from a light metal alloy. 2. The method according to claim 1, characterized in that the method for Production of a seat shell of a motor vehicle seat is used. 3. The method according to claim 1, characterized in that the method for Production of a body part is used. 4. The method according to claim 3, characterized in that the method for Production of a rear lid inner panel is used. 5. The method according to claim 3, characterized in that the method for Production of an engine compartment lid inner panel is used. 6. The method according to claim 3, characterized in that the method for Production of a door inner panel is used. 7. The method according to any one of claims 1 to 6, characterized in that the Light metal alloy is an aluminum alloy. 8. The method according to claim 7, characterized in that the aluminum alloy Magnesium-containing aluminum alloy. 9. The method according to any one of claims 1 to 6, characterized in that the  Light metal alloy is a magnesium alloy.   10. The method according to claim 9, characterized in that the magnesium alloy is an aluminum-containing magnesium alloy. 11. The method according to any one of claims 1 to 10, characterized in that the motor vehicle part is made from a sheet metal semi-finished product ( 13 ). 12. The method according to claim 11, characterized in that the sheet metal semi-finished product ( 13 ) is a thin sheet semi-finished product with a thickness between 0.5 mm and 3 mm. 13. The method according to any one of claims 1 to 12, characterized in that the Gas pressure for superplastic forming during superplastic Forming process is controlled to ensure a defined forming stress. 14. The method according to any one of claims 1 to 13, characterized in that the Gas pressure for superplastic forming is between 5 bar and 40 bar. 15. The method according to claim 14, characterized in that the gas pressure for superplastic forming is between 8 bar and 15 bar. 16. The method according to any one of claims 1 to 15, characterized in that the forming speed in superplastic forming is between 10 ^-2 s ^-1 and 10 ^-4 s ^-1 . 17. The method according to claim 16, characterized in that the forming speed in superplastic forming is between 10 ^-3 s ^-1 and 10 ^-4 s ^-1 . 18. The method according to any one of claims 1 to 17, characterized in that on the side ( 17 ) of the semi-finished product ( 13 a), which is opposite the side pressurized by a pressurized gas for superplastic forming ( 16 ), during the superplastic forming at least temporarily there is also an increased gas pressure. 19. The method according to any one of claims 1 to 18, characterized in that the for superplastic forming necessary gas pressure through a pressurized Noble gas or noble gas mixture is applied. 20. The method according to any one of claims 1 to 19, characterized in that in the method at least two motor vehicle parts are produced simultaneously in one device ( 1 ). 21. Motor vehicle part, characterized in that the motor vehicle part by superplastic forming is made of a light metal alloy. 22. Motor vehicle part according to claim 21, characterized in that the motor vehicle is a seat shell of a motor vehicle seat. 23. Motor vehicle part according to claim 21, characterized in that the motor vehicle is a Body part is. 24. Motor vehicle part according to claim 23, characterized in that the body part is a rear lid inner panel. 25. Motor vehicle part according to claim 23, characterized in that the body part is an engine compartment lid inner panel. 26. Motor vehicle part according to claim 23, characterized in that the body part is a door inner panel. 27. Motor vehicle part according to one of claims 21 to 26, characterized in that the motor vehicle part by superplastic forming from an aluminum alloy is made. 28. Motor vehicle part according to claim 27, characterized in that the motor vehicle part through superplastic forming from a magnesium-containing aluminum alloy is made.   29. Motor vehicle part according to one of claims 21 to 26, characterized in that the automotive part through superplastic forming from a magnesium alloy is made. 30. Motor vehicle part according to claim 29, characterized in that the motor vehicle part through superplastic forming from an aluminum-containing magnesium alloy is made. 31. Motor vehicle part according to one of claims 21 to 30, characterized in that the motor vehicle part is produced by superplastic forming from a sheet metal semi-finished product ( 13 ). 32. Motor vehicle part according to claim 31, characterized in that the motor vehicle part through superplastic forming from a thin sheet of semi-finished product with a thickness is made between 0.5 mm and 3 mm.