EP2886216A1 - Production method for metal sheets made of magnesium and high-strength aluminium - Google Patents

Abstract

The weight-saving use of sheet metal parts made of magnesium and high-strength aluminum (11) in the automotive industry requires an industrial manufacturing process with a high level of vertical integration without quality defects. For this purpose, the unwound from a coil (7), directed sheet metal strip (10) or cut blanks (13) in an adjacent multi-stage tool (4) to 120 to 380 ° C working temperature to heat and in this constant temperature maintained throughout all individual tool stages finished. Characteristic of the method is a € ¢ Thorough continuous heating of the sheet metal parts in the input position (1) and multiple € ¢ supplementary and controllable warm-up at the individual tool stages in the production positions (2), which can be carried out both in progressive tools and in transfer tools

Description

The invention is based on the method defined in the preamble of claim 1.

The state of the art is that in order to ensure good quality, these sheet metal parts to be produced from magnesium and high-strength aluminum are to be processed in a process window, lying at a working temperature between 120 and 380 ° C.

• WO 2012/055688 A1
  ein Verfahren und eine Anlage zur Herstellung jeweils nur eines von den förmigen Magnesiumblech-Teilen beschrieben.
  Die Anlage besteht aus einem abkühlbaren Umformwerkzeug mit Stempel und Matrize, wobei die Magnesiumblech-Teile mit einer Greifvorrichtung einzeln von einer separat angeordneten Teile-Erwärmungsvorrichtung entnommen und in dieses Einzelwerkzeug eingelegt werden. Nach dem Formen wird das Magnesiumblech-Teil mit einer zweiten Greifvorrichtung aus dem Umformwerkzeug entnommen und abgestapelt.
• DD 202 403 A
  beinhaltet eine Einrichtung zur beheizten Herstellung von Blechteilen aus Blechbändern, wobei das Umformwerkzeug aus mehreren Einzelwerkzeugen besteht. Es ist ebenfalls abkühlbar. Die Teile-Erwärmungsvorrichtung ist brückenartig über den Blechbändern und separat in einem Abstand vor dem Umformwerkzeug angeordnet.
• DE 101 28 199 B4
  beinhaltet eine Vorrichtung zur Umformung von Magnesiumblechen, wobei mit einem Einzelwerkzeug eine Wölbung mittels zweier Abrundungen und einer Abkantung in eine Blechtafel eingearbeitet wird. Die Teil-Erwärmungsvorrichtung ist eine Gasheizung, wobei die Gasflammen an den Aktivflächen des Einzelwerkzeuges und an dem Magnesiumblech-Verformungsflächen wirken und diese kontaktieren.
• DE 10 2011 051 943 A1 ,
• DE 10 2010 005 263 A1 und
• DE 10 2009 000 981 T5
  beinhalten weiterhin Formwerkzeuge mit denen die Bearbeitung erwärmter Blechzuschnitte und Platinen aus hochfestem Aluminium bestehend durchführbar ist.
  Aus technischen Gründen verfügen diese Werkzeuge aber nur über Bearbeitungsstellen und Formstationen mit jeweils einer Fertigungsstufe. Damit sind diese Ausbildungen in einem individuellen, mehrstufigen Schneid- und Formteilfertigung nicht einsetzbar.

Exemplary of other prior art inventive solution descriptions are in

• WO 2012/055688 A1
  a method and an apparatus for producing only one of the shaped magnesium sheet parts described.
  The system consists of a coolable forming tool with punch and die, wherein the magnesium sheet parts are removed with a gripping device individually from a separately arranged parts heating device and inserted into this single tool. After molding, the magnesium sheet part is removed from the forming tool with a second gripping device and stacked.
• DD 202 403 A
  includes a device for heated production of sheet metal parts from sheet-metal strips, wherein the forming tool consists of several individual tools. It is also coolable. The parts-heating device is arranged like a bridge over the metal bands and separately at a distance in front of the forming tool.
• DE 101 28 199 B4
  includes a device for forming magnesium sheets, wherein a buckle by means of two rounding and a fold is incorporated into a metal sheet with a single tool. The partial heater is a gas heater wherein the gas flames act on and contact the active surfaces of the single tool and the magnesium sheet deformation surfaces.
• DE 10 2011 051 943 A1 .
• DE 10 2010 005 263 A1 and
• DE 10 2009 000 981 T5
  also include molds with which the processing of heated sheet metal blanks and boards made of high-strength aluminum is feasible.
  For technical reasons, however, these tools only have processing stations and forming stations, each with a production level. Thus, these training in an individual, multi-stage cutting and molding production can not be used.

• die Erwärmungsvorrichtung zur Erwärmung von Blechteilen und Platinen in der Ausbildung als Blechbänder oder als zugeschnittene Blechtafeln und Platinen separiert von dem Bearbeitungswerkzeug zur Teileherstellung angeordnet sind und damit eine verfahrensbehindernde Abkühlung bereits vor der ersten Bearbeitung erfolgt,
• an den Einzelwerkzeugen in dem Bearbeitungswerkzeug keine Nacherwärmung oder temperaturkonstanthaltende Aufheizung der Aktivflächen durchführbar ist, so dass an den Schnitt- und Formflächen optische und technologische Funktions- und Qualitätsmängel entstehen können,
• bei Erwärmung der Magnesiumblech-Teilen mittels Gasheizungen durch die unmittelbare Flammeneinwirkung auf die Schnitt- und Formflächen ebenfalls optische und technologische Qualitätsmängel feststellbar sein werden und dass
• diese bekannten Verfahren und Werkzeugkonstruktionen keine industrielle Herstellung mit großer Fertigungstiefe in Folgeverbundwerkzeugen und Transferwerkzeugen mit einer großen Anzahl von Verfahrensschritten zum Schneiden, Formen und Ausschneiden in Einzelwerkzeugstufen nicht erlauben, da sie jeweils für nur eine Fertigungsstufe konzipiert sind.

A disadvantage of these inventive solutions that

• the heating device for heating sheet metal parts and blanks in the form of metal strips or cut sheet metal plates and blanks separated from the machining tool for parts production are arranged and thus a process-hindering cooling takes place even before the first processing,
• no reheating or constant temperature heating of the active surfaces can be carried out on the individual tools in the processing tool so that optical and technological defects in function and quality can arise at the cutting and shaping surfaces,
• When heating the magnesium sheet parts by means of gas heaters by the direct action of flame on the cutting and shaping surfaces also optical and technological quality defects will be detectable and that
• These known methods and tool designs do not allow industrial production with large vertical integration in progressive tools and transfer tools with a large number of process steps for cutting, forming and cutting in individual tool stages, since they are each designed for only one manufacturing stage.

• nach einer grundhaften Erwärmung von Blechband oder Platinen verfahrensbehindernde Abkühlungen oder Zwischenabkühlungen von der ersten Bearbeitung vermieden werden,
• ergänzende Erwärmungen an den Einzelwerkzeugstufen zum Ausgleich von Temperaturverlusten und zur Konstanthaltung der nominellen Arbeitstemperatur ermöglicht werden,
• optische und technologische Qualitätsmängel an den Aktivflächen der Einzelwerkzeugstufen und an den Schnitt- und Formflächen der Blechteile aus Magnesium- und hochfesten Aluminiumteile ausgeschlossen sind,
• ein industrielles Herstellungsverfahren mit großer Fertigungstiefe in einem laufenden Prozess realisierbar ist,
  und dass
• die Anwendungsvorteile von Blechteilen aus Magnesium und aus hochfesten Aluminiumteilen im Automobilbau und in anderen Produktherstellungsbereichen bezogen auf Leichtgewichtigkeit, Kostenminimierung und Qualität voll zum tragen kommen.

The indicated in claim 1 invention is therefore based on the problem that the method for the production of sheet metal parts of magnesium and high-strength aluminum in such a way that

• avoid process-slowing cooling or intermediate cooling of the first processing after a thorough heating of sheet metal strip or blanks,
• supplemental heating at the individual tool stages to compensate for temperature losses and to keep the nominal working temperature constant,
• optical and technological quality defects on the active surfaces of the individual tool steps and on the cutting and forming surfaces of the sheet metal parts of magnesium and high-strength aluminum parts are excluded,
• an industrial production process with large vertical range of manufacture can be realized in a running process,
  and that
• The application advantages of sheet metal parts made of magnesium and high-strength aluminum parts in the automotive industry and in other product manufacturing areas based on lightweight, cost minimization and quality come to fruition.

• Alle für die qualitative Herstellung von Blechteilen aus Magnesium und aus hochfesten Aluminiumteilen erforderlichen Verfahrensschritte laufen durchgängig, nacheinander getaktet sowie gesteuert in einem Folgeverbundwerkzeug oder in einem Transferwerkzeug ab. Unmittelbar nach dem Abrollen vom Coil wird das vorher gerichtete Blechband, bzw. die Platinen im angrenzenden mehrstufigen Werkzeug in einer Schienenbahn oder zwischen Greiferbacken einer Greifvorrichtung gehalten, positioniert und geführt.

This problem is solved by the patent claim 1, and supplemented by the claims 2 and 3, as follows:

• All required for the qualitative production of sheet metal parts made of magnesium and high-strength aluminum parts process steps run consistently, one after the other timed and controlled in a progressive tool or in a transfer tool. Immediately after unwinding from the coil, the previously directed sheet metal strip or the blanks are held and guided in the adjacent multi-stage tool in a rail track or between gripper jaws of a gripping device.

• ein mehrfaches Schneiden, Formen und Ausschneiden mittels Einzelwerkzeugstufen und gleichzeitig
• eine ausreichend ergänzende Aufwärmung auf die Temperatur der in der Eingangsposition erzeugten Erwärmung des Blechbandes, der Platinen oder der Blechteile zum Zwecke einer Temperatur-Konstanthaltung an den Aktivflächen der Einzelwerkzeugstufen, ausgehend von Basispunktstellungen realisierbar.

Sequentially, the sheet metal strip or the cut in an input position experience a thorough, continuous heating on and between heating components. In a row of further ordered production positions is

• a multiple cutting, shaping and cutting by means of individual tool stages and simultaneously
• a sufficiently complementary heating to the temperature of the generated in the input position heating of the sheet metal strip, the boards or the sheet metal parts for the purpose of a temperature-constant maintenance on the active surfaces of the individual tool stages, starting from base point positions feasible.

In a discharge and ejection position, the finished sheet metal parts from the multi-stage tool can be dissipated and transported away by means of part-specific structured transport means.

Further process designs are specified in claims 2 and 3: They relate to the structure, the arrangement and dimensioning of the individual tool stages in the upper and in the lower part of a follow-on composite tool or transfer tool and conditions of partial heating to the working temperatures and a directed and opposite thermal expansion by a defined heat development , as well as controllability.

By the method features mentioned in the claims, the stated disadvantages of the prior art are overcome and solved the problems.

The invention and its application is explained in the following part of the description in addition. In the FIGS. 1 and 2 is the process, running in a multi-stage tool, simplified with a low number of steps equipped graphically.

The magnesium and aluminum sheet for laminar components provided by several specialist companies is as in Fig. 1 shown as a thin sheet metal strip 10 from a coil 7 directly removable and unrolled. Essential working means of the method for producing the magnesium and high-strength aluminum sheet metal parts 11 is an eight-step progressive tool. 4

In its input position 1 is a brief basic heating of the sheet metal strip 10 by means of flat heating components 5 instead. For the further process implementation, a temperature process window is available, since the magnesium material also requires a specific working temperature for its processing in good quality.

In the manufacturing positions 2, the individual tool stages for cutting, forming and cutting the magnesium sheet metal parts 11 with and out of the sheet metal strip 10 take place in six stages.

• die Konstanthaltung einer einheitlichen Arbeitstemperatur, ohne Überhitzungseffekte sowie
• eine geringe und gleichbleibende oder ausgeglichene Eigentemperatur der Einzelwerkzeugstufen sowie der Temperaturen in den Ober- und Unterteilen des Folgeverbundwerkzeuges 4.

Ensure that the heating components 5 are arranged on and in the active surfaces of the individual tool stages in the production positions 2

• the constant maintenance of a uniform working temperature, without overheating effects as well
• a low and constant or balanced natural temperature of the individual tool stages and the temperatures in the upper and lower parts of the progressive tool 4.

The quality-determining positioning and guiding the sheet metal strip 10 ensures the rail track 6 over the entire length of the progressive tool 4. In the discharge and ejection positions 3 of the progressive tool 4, the derivation of the finished magnesium sheet parts 11 takes place via slides in the container-shaped transport 8 and Derivation of the residual material of the metal strips 10 in suitable pallet-like transport 9th

In Fig. 2 the multi-stage tool 4 is designed as a transfer tool. In terms of process technology, the previously cold-cut blanks 13 made of magnesium or high-strength aluminum are held by means of gripper jaws 14 and undergo a timed, stepwise transport from single tool stage to single tool stage in the direction of process sequence 12. Comparable to the in Fig. 1 process shown process the sheet metal parts in the input position 1 a basic heating to working temperature and in the production position 2, the constant maintenance of this working temperature. LIST OF REFERENCE NUMBERS 1 Input position at 4 2 Manufacturing locations at 4 3 Discharge and ejection position at 4 4 multi-stage tool 5 Heating components 6 rail track for 10 7 coil 8th Mode of Transport 9 Mode of Transport 10 metal strip 11 Magnesium sheet part (s) 12 Direction of the procedure 13 boards 14 gripper jaws 15 Interface for boards

Claims (3)

Production method for sheet metal parts made of magnesium and high-strength aluminum characterized by a large vertical integration characterized industrial production while maintaining material-related and part-specific operating temperatures characterized
that all necessary process steps are continuous, clocked in sequence and controlled in a multi-stage tool (4), wherein immediately after rolling from the coil (7) directed sheet metal strip (10) and after cutting boards (13) in the adjacent multi-stage tool (4) in a rail track (6) or held between gripper jaws (14), is positioned and guided,
that successively the sheet metal strip (10) or the boards (13) In an input position (1) undergoes a fundamental heating on or between heating components (5), • in a series of further series production positions (2) a multiple cutting, shaping and cutting by means of individual tool stages feasible and at the same time sufficient supplementary heating to the temperature of the input position (1) generated heating of the sheet metal strip (10), the boards (13) or the sheet metal parts for the purpose of maintaining constant temperature on the active surfaces of the individual tool stages, starting from base point positions of further heating components (5) can be realized and • in a discharge and ejection position (3) the finished sheet metal parts from the multi-stage tool (4) by means of part-specific structured transport (8 and 9] are derivable and can be transported away. Production method for sheet metal parts made of magnesium and high-strength aluminum according to claim 1, characterized
that by a segmented structure, an insulating separation arrangement and a small dimensioning of the individual tool stages in the upper and in the lower part of the multi-stage tool (4) in its manufacturing positions (2) only partial heating connected with a low thermal expansion, by a balancing radially structured and also oppositely acting thermal expansion conditioned, is feasible. Manufacturing method for sheet metal parts made of magnesium and high-strength aluminum according to claim 1 and 2, characterized
in that a heat-difference-dependent activation and deactivation of all heating components (5) in the production positions (2) and their energy supply can be regulated by the different heating temperatures present concretely on the active surfaces of the individual tool stages.

Images