DE102016114423A1 - Method and device for pressure forming hollow profiles - Google Patents

Abstract

The invention relates to a method and a device for pressure forming of hollow profiles with a forming fluid. In order to reduce the operating costs in the pressure forming of hollow sections, the method according to the invention comprises the following steps: Step A: Reduction of a volume which can be absorbed by the forming fluid within a hollow profile semifinished product (1). Step B: heating of the hollow profile semifinished product (1). Step C: Forming the heated hollow profile semi-finished product (1) by the pressurized forming fluid.

Description

The present invention relates to a method and a device for pressure forming of hollow sections, in particular a method and a device for adjusting final product properties of hollow sections in tempered pressure forming processes.

Technical problem

When press hardening and / or quenching of hollow sections of metal, in particular of steel or aluminum, a gas is used as the forming medium in the rule. The semifinished product is subjected to deformation, e.g. heated in an oven, with an inductor, by conduction or contact heating and then positioned with an automatic or manual handling in a tool for forming. The tool for the forming consists of a top and a bottom part, which are installed in a press or the like. The semi-finished product is then inserted into this tool. Then the tool is closed and sealed at the pipe ends by axial sealing units. Only then can the forming process be started.

The forming medium, here a gas, is fed into the component from a gas pressure generator unit via hoses or pipes. It is very important from the point of view of forming technology that the pressure build-up (up to 1,200 bar) must be very fast. Pressure build-up rates of up to 1000 bar / second should be achieved.

This extremely fast compression of the gas leads to the actual technical problem. The pressure buildup rate is highly dependent on the volume of the component. Component volumes of up to 15 liters can already occur. In order to compress these component volumes at a high internal pressure, large pressure accumulators and compressors are required on the gas pressure generator unit.

This is economically very expensive, since the total amount of gas required in these stores must also be pre-compressed, which ultimately requires a lot of energy but also time. In mass production cycle times of 20 to 30 seconds are common in this forming technology. This requires great effort to provide or provide these required gas volumes. In the sense of resource-efficient production, other more economical solutions must be found.

The invention is therefore based on the object to reduce the operating costs in the pressure forming of hollow sections and to provide a suitable method and a device suitable for this purpose.

• – Schritt A: Verringerung eines durch das Umformfluid einnehmbaren Volumens innerhalb eines Hohlprofil-Halbzeugs.
• – Schritt B: Erwärmen des Hohlprofil-Halbzeugs.
• – Schritt C: Umformen des erwärmten Hohlprofil-Halbzeugs durch das mit Druck beaufschlagte Umformfluid.

The invention is achieved with regard to the method by the subject-matter of claim 1. The method according to the invention for pressure-forming hollow profiles with a forming fluid comprises the following steps:

• Step A: Reduction of a volume which can be absorbed by the forming fluid within a hollow profile semifinished product.
• - Step B: heating of the hollow profile semi-finished product.
• - Step C: forming the heated hollow profile semi-finished by the pressurized forming fluid.

• – Einströmendes Umformfluid sollte an der gesamten Innenfläche und zur gleichen Zeit wirken, als wäre keine reduzierende Maßnahme des Bauteilvolumens im Hohlprofil vorhanden.
• – Die reduzierende Maßnahme des Bauteilvolumens im Hohlprofil sollte temperaturbeständig bis 1100 Grad sein und keine chemischen Reaktionen mit dem Halbzeug eingehen.
• – Das Einbringen aber auch das Ausbringen dieser Maßnahme im Inneren des Hohlprofils sollte keinen großen zusätzlichen Arbeitsschritt generieren und die Taktzeit der Produktion nicht verlangsamen.

The approach according to the invention for the solution of the abovementioned technical problem is the reduction of the component volume in the hollow profile semifinished product, so that a significantly smaller amount of forming fluid is required for pressure deformation of the hollow profile semifinished product. The following implementation requirements should be taken into account:

• - Inflowing forming fluid should act on the entire inner surface and at the same time, as if no reduction measure of the component volume in the hollow profile available.
• - The reducing measure of the component volume in the hollow profile should be temperature resistant up to 1100 degrees and should not undergo chemical reactions with the semifinished product.
• - The introduction but also the application of this measure inside the hollow profile should not generate much additional work and not slow down the cycle time of production.

The reduction of the ingestible by the forming fluid volume is preferably accomplished by a filling. It does not matter whether a filling introduced into the interior of the hollow profile semifinished product or the hollow profile semifinished product, for. is applied to a filling. The decisive factor is that the volume that can be absorbed by the forming fluid is reduced.

With regard to the expansion of the process limits in the transformation and application of new technologies as well as an efficient method integration of the temperature factor, the below-mentioned embodiments of the invention, which are subject matters of the subclaims, are also advantageous.

• – Schritt A1: Bereitstellen des Hohlprofil-Halbzeugs, beispielsweise aus Metall, insbesondere aus Stahl oder Aluminium, vorzugsweise in Form eines Rohres, das sich entlang einer geraden und/oder gekrümmten Rohrachse erstreckt, wobei das Rohr bevorzugt ein oder zwei offene Enden aufweist, wobei das Rohr besonders bevorzugt über wenigstens einen Teil entlang der Rohrachse oder entlang der gesamten Rohrachse einen konstanten Querschnitt aufweist.
• – Schritt A2: Biegen und/oder Mechanisches Formen des Hohlprofil-Halbzeugs, vorzugsweise in die bestimmungsgemäße Form des Endprodukts.
• – Schritt A3: Beschichten des Hohlprofil-Halbzeugs gegen Verzunderung.
• – Schritt A4: Befüllen eines, mehrerer, oder sämtlicher Hohlräume des Hohlprofil-Halbzeugs, vorzugsweise derart, dass der Hohlraum/die Hohlräume teilweise oder vollständig befüllt ist/sind, bevorzugt derart, dass das einzubringende Umformfluid auf die Innenwand/Innenwände des befüllten Hohlprofil-Halbzeugs wirken kann.
• – Schritt A5: Befüllen des Hohlprofil-Halbzeugs mit einem losen Füllmaterial, das vorzugsweise derart beschaffen ist, dass es das durch das Umformfluid einnehmbare Volumen selbsttätig einnimmt, wobei das lose Füllmaterial bevorzugt ausgewählt ist aus einer Gruppe von Füllmaterialien, umfassend: Schüttgut, beispielsweise Sand, insbesondere temperaturbeständigen Quarzsand, oder Perlen, beispielsweise Zirkoniaperlen.
• – Schritt A6: Befüllen des Hohlprofil-Halbzeugs mit einem flexiblen und/oder formbaren und/oder formveränderlichen Füllmaterial, das vorzugsweise derart beschaffen ist, dass es sich beim Befüllen des Hohlprofil-Halbzeugs einer Innenkontur des Hohlprofil-Halbzeugs anpasst, wobei das Füllmaterial bevorzugt ausgewählt ist aus einer Gruppe von Füllmaterialien, umfassend: Draht, insbesondere Stahldraht, hochtemperaturfesten Heizdraht, eine Teleskopiereinrichtung wie einen Teleskopzylinder mit einem Vollzylinder und wenigstens einem gegenüber dem Vollzylinder bewegbaren Hohlzylinder.
• – Schritt A7: Befüllen des Hohlprofil-Halbzeugs mit einem festen Füllmaterial, das vorzugsweise einer Innenkontur des Hohlprofil-Halbzeugs angepasst ist, wobei das feste Füllmaterial bevorzugt ausgewählt ist aus einer Gruppe von Füllmaterialien, umfassend: Stäbe, Stangen, Dorne.
• – Schritt A8: Befüllen des Hohlprofil-Halbzeugs mit einer beheizbaren und/oder beheizten Füllung, sodass dem Hohlprofil-Halbzeug wenigstens ein Teil der oder die gesamte erforderliche Wärmemenge im Rahmen des Schritts B über die Füllung zugeführt werden kann.
• – Schritt A9: Fixieren der Füllung innerhalb des Hohlprofil-Halbzeugs, um eine Bewegung der Füllung gegenüber dem Hohlprofil-Halbzeug zu verhindern.
• – Schritt A10: Verschließen einer, mehrerer oder sämtlicher Zugangsöffnungen des befüllten Hohlprofil-Halbzeugs, um ein Austreten der Füllung aus dem Hohlprofil-Halbzeug zu verhindern.

It may be advantageous for step A to comprise at least one of the following substeps:

• Step A1: providing the hollow profile semifinished product, for example made of metal, in particular of steel or aluminum, preferably in the form of a tube extending along a straight and / or or curved pipe axis, wherein the tube preferably has one or two open ends, wherein the tube particularly preferably has a constant cross section over at least one part along the tube axis or along the entire tube axis.
• Step A2: Bending and / or mechanical shaping of the hollow profile semi-finished product, preferably into the intended shape of the end product.
• - Step A3: coating the hollow profile semi-finished product against scaling.
• Step A4: filling one, several, or all cavities of the hollow profile semi-finished product, preferably such that the cavity / cavities is / are partially or completely filled, preferably such that the forming fluid to be introduced onto the inner wall / inner walls of the filled hollow profile Semi-finished can act.
• Step A5: filling the hollow section semifinished product with a loose filling material which is preferably such that it automatically occupies the volume which can be taken up by the forming fluid, wherein the loose filling material is preferably selected from a group of filling materials comprising: bulk material, for example sand , in particular temperature-resistant quartz sand, or pearls, for example Zirkoniaperlen.
• - Step A6: filling the hollow profile semi-finished product with a flexible and / or moldable and / or variable shape filler material, which is preferably such that it adapts to an inner contour of the hollow profile semifinished product when filling the hollow profile semifinished product, wherein the filler material is preferably selected is from a group of filling materials, comprising: wire, in particular steel wire, high-temperature resistant heating wire, a telescoping device such as a telescopic cylinder with a solid cylinder and at least one hollow cylinder movable relative to the solid cylinder.
• Step A7: filling the hollow profile semi-finished product with a solid filler material, which is preferably adapted to an inner contour of the hollow profile semi-finished product, wherein the solid filler material is preferably selected from a group of filler materials, comprising: rods, rods, mandrels.
• - Step A8: filling the hollow profile semi-finished product with a heated and / or heated filling, so that the hollow profile semi-finished at least a portion of or the total amount of heat required in the context of step B can be supplied via the filling.
• - Step A9: Fixing the filling within the hollow profile semi-finished product in order to prevent movement of the filling relative to the hollow profile semi-finished product.
• Step A10: Closing one, several or all access openings of the filled hollow profile semifinished product in order to prevent the filling from emerging from the hollow profile semifinished product.

The sub-steps mentioned can be carried out in the order given or, if expedient and meaningful, in any other order, if appropriate with omission of one or more sub-steps. By virtue of the measures mentioned, the volume which can be absorbed by the shaping fluid can be effectively reduced within the hollow-section semifinished product, so that the amount of forming fluid required for the pressure-forming can be significantly reduced as a result.

Preferably, the loose filler is a bulk material, i. a granular or lumpy mixture which is in a pourable form. The properties of bulk material are determined by the grain size and the grain distribution as well as the bulk density, the angle of repose, the humidity and the temperature. When using a loose filling material, it proves to be useful if the bulk density is chosen such that the forming fluid can reach the inner walls of the hollow profile semi-finished in any case well.

The effect of reducing the ingestible volume of the forming fluid is particularly advantageous when the filling itself is not penetrated by the forming fluid. Insofar, fillings or filling materials with a closed and pressure-tight surface, in particular fillings or filling materials made of solid material, are particularly suitable.

• – Schritt B1: Erwärmen des Hohlprofil-Halbzeugs durch Induktion, Konduktion, Kontakterwärmung oder im Ofen.
• – Schritt B2: Erwärmen des Hohlprofil-Halbzeugs auf eine Austenitisierungstemperatur (bei Stahl) oder Lösungsglühtemperatur (bei Aluminium).
• – Schritt B3: Erwärmen des Hohlprofil-Halbzeugs auf eine Arbeitstemperatur im Bereich von 500 bis 1100 °C, vorzugsweise von 550 bis 1100 °C.

However, it can also be useful if step B comprises at least one of the following substeps:

• - Step B1: heating of the hollow profile semi-finished product by induction, conduction, contact heating or in the oven.
• Step B2: Heating the hollow section semifinished product to an austenitizing temperature (in the case of steel) or solution annealing temperature (in the case of aluminum).
• Step B3: heating the hollow section semifinished product to a working temperature in the range from 500 to 1100 ° C, preferably from 550 to 1100 ° C.

The heating of the hollow profile semifinished product can take place before and / or after and / or simultaneously with the introduction of the filling. The sub-steps mentioned can be carried out in the order given or, if expedient and meaningful, in any other order, if appropriate with omission of one or more sub-steps.

• – Schritt C1: Einbringen des befüllten und erwärmten Hohlprofil-Halbzeugs in ein Werkzeug zur Umformung, vorzugsweise durch ein automatisches Handling.
• – Schritt C2: Verschließen und/oder Abdichten des Hohlprofil-Halbzeugs, vorzugsweise durch eine oder mehrere Dichteinheiten, wobei die eine oder mehrere Dichteinheiten bevorzugt eine oder mehrere Zugangsöffnungen des Hohlprofil-Halbzeugs verschließt/verschließen.
• – Schritt C3: Bereitstellen eines gasförmigen Umformfluids, vorzugsweise Luft, Stickstoff oder Argon.
• – Schritt C4: Bereitstellen eines mit Druck beaufschlagten Umformfluids außerhalb des Hohlprofil-Halbzeugs, vorzugsweise in einem Druckspeicher, bevorzugt auf Arbeitsdruck.
• – Schritt C5: Einleiten des mit Druck beaufschlagten Umformfluids in das Hohlprofil-Halbzeug, vorzugsweise durch Überführung des Umformfluids aus einem Druckspeicher.
• – Schritt C6: Erhöhen des Drucks innerhalb des Hohlprofil-Halbzeugs mit einer Druckaufbaurate im Bereich von 10 bis 1000 bar pro Sekunde, bevorzugt im Bereich von 500 bis 1000 bar pro Sekunde, besonders bevorzugt im Bereich von 800 bis 1000 bar pro Sekunde.
• – Schritt C7: Erhöhen des Drucks innerhalb des Hohlprofil-Halbzeugs auf einen Arbeitsdruck, wobei der Arbeitsdruck vorzugsweise im Bereich von 1 bis 1200 bar, bevorzugt im Bereich von 100 bis 1200 bar, besonders bevorzugt im Bereich von 300 bis 1200 bar liegt.
• – Schritt C8: Filterung des Umformfluids beim Ablassen aus dem Hohlprofil-Halbzeug nach erfolgter Umformung, um Füllung und Umformfluid voneinander zu trennen.
• – Schritt C9: Entfernen der Füllung aus dem umgeformten Hohlprofil, vorzugsweise im abgekühlten Zustand.

However, it can also be useful if step C comprises at least one of the following substeps:

• - Step C1: introducing the filled and heated hollow profile semi-finished product into a tool for forming, preferably by an automatic handling.
• Step C2: Closing and / or sealing the hollow profile semifinished product, preferably by one or more sealing units, wherein the one or more sealing units preferably closes / closes one or more access openings of the hollow profile semifinished product.
• Step C3: providing a gaseous forming fluid, preferably air, nitrogen or argon.
• Step C4: Provision of a pressurized forming fluid outside the hollow profile semifinished product, preferably in an accumulator, preferably at working pressure.
• - Step C5: introducing the pressurized forming fluid into the hollow profile semi-finished product, preferably by transferring the forming fluid from a pressure accumulator.
• Step C6: increasing the pressure within the hollow profile semifinished product at a pressure build-up rate in the range of 10 to 1000 bar per second, preferably in the range of 500 to 1000 bar per second, more preferably in the range of 800 to 1000 bar per second.
• Step C7: increasing the pressure within the hollow profile semifinished product to a working pressure, the working pressure preferably being in the range from 1 to 1200 bar, preferably in the range from 100 to 1200 bar, particularly preferably in the range from 300 to 1200 bar.
• Step C8: filtering the forming fluid as it is discharged from the hollow section semi-finished product after forming to separate the filling and forming fluid.
• Step C9: removal of the filling from the formed hollow profile, preferably in the cooled state.

The sub-steps mentioned can be carried out in the order given or, if expedient and meaningful, in any other order, if appropriate with omission of one or more sub-steps.

It may be advantageous if steps A to C are repeated in cycle times of up to 60 seconds, preferably up to 45 seconds, preferably up to 30 or 20 seconds.

The object of the invention is achieved with regard to the device by the subject matter of claim 6, relating to a device for pressure forming of hollow profiles by the method according to one of the preceding embodiments.

Further advantageous developments of the invention will become apparent by any combination of the features disclosed in this application.

Brief description of the figures

1 shows a schematic, perspective view (a) and a schematic front view (b) of a process according to the invention to be processed hollow profile semi-finished product.

2 shows a schematic view of a forming tool and connected to a pressure accumulator and provided with filling and heated hollow profile semi-finished product after step C of the method according to the invention.

Detailed Description of the Preferred Embodiment

In step A of the method according to the invention, ie before heating in the context of step B, the tubular hollow profile semi-finished products 1 bent and mechanically preformed if necessary. If necessary, then the bent or preformed hollow profile semi-finished products 1 coated against scaling.

In order to reduce the volume which can be taken up by the forming fluid and consequently the necessary amount of the forming fluid, the hollow profile semi-finished products are heated prior to heating 1 a filling 2 introduced into the tube interior. Basically, the stuffing 2 be distinguished in loose or solid filler.

If loose filling material, for example temperature-resistant quartz sand or zirconia pearls or another comparable loose filling material, into the hollow profile semi-finished product 1 is introduced before heating, then the ends of the hollow profile semi-finished product 1 be closed for handling in the further course of the procedure, so that no filling material can escape during handling. In the process, the sealing of the ends of the tubular hollow profile semifinished product 1 via axial cylinder with the assembled sealing dies for closing and sealing a pressure chamber 3 be accomplished. The cavity in the interior of the hollow profile semi-finished product 1 But now it should not be completely filled with the loose filling material, but only so much that the pressure on the inner surfaces of the hollow profile semi-finished product 1 can attack and act. After forming, and in particular during pressure reduction, it must be prevented via a specific filter system that components of the loose filling material are sucked into the pressure lines or into the system. Alternatively, the amount of gas can be discharged via a certain pressure outlet side (for example, at the other end of the pipe component). Thus, damage to the system is avoided.

Solid filling material may be, for example, steel wire (in particular high-temperature resistant heating wire), which is pushed into the bent component before heating and can be adapted by the small diameter of the semi-finished shape (bent preform). This can also be done as a bundle. When handling the pipe ends must not be completely closed, would be helpful here a kind of half-shell, so that a slipping can be avoided.

Alternatively, a round bar in the hollow profile semi-finished product 1 be introduced. However, this requires that the bends in the hollow profile semi-finished product 1 are not too large and that the round rod is smaller than the diameter of the hollow profile semi-finished product 1 , The round rod should then be fixed at the ends, so that it is not a one-sided position in the hollow profile semi-finished product 1 comes.

In the case of straight components or components with long and straight semi-finished parts, the volume of the component can also be reduced with the aid of a telescopic cylinder and a solid cylinder (round rod) mounted thereon. After inserting the hot hollow profile semi-finished product 1 The cylinder approaches the pipe ends, at the same time the integrated telescopic cylinder is in the hollow profile semi-finished product 1 retracted and reduces the dead volume in the component.

In step B of the method according to the invention then the curved, coated and filled hollow profile semi-finished products 1 to a certain austenitizing temperature (for steel) or solution annealing temperature (for aluminum). This can be between 500 and 1100 degrees, depending on the application. Austenitizing temperature and duration depend on the materials used, the wall thickness of the hollow profile semi-finished product 1 and the necessary degrees of deformation that are driven in the process. The semifinished product is heated, for example, in a furnace or with an inductor.

In step C of the process according to the invention is filled with 2 provided and heated hollow profile semi-finished product 1 with automatic or manual handling in a forming tool 3 positioned. Then the tool closes 3 and there is a seal of the pipe ends of the hollow profile semi-finished product 1 through axial sealing units. From an accumulator 4 Subsequently, a pressurized forming gas such as air, nitrogen or argon via hoses or pipes in the hollow profile semi-finished product 1 initiated. With pressure build-up rates of up to 1000 bar / second, the forming pressure of up to 1,200 bar is reached very quickly.

Due to the filling 2 inside the hollow profile semi-finished product 1 is the amount of gas required for pressure deformation compared to an unfilled hollow profile semi-finished product 1 much lower, so the accumulator 4 can be downsized. The amount of gas required for pressure forming can therefore also be compressed much faster and with less energy and brought to the intended forming pressure.

The application of a loose filling material from the formed component is achieved by pouring out or blowing out after the forming in the cooled state. Subsequent cleaning of the inside of the pipe can be carried out if necessary or necessary.

The main advantages of the invention can be summarized as follows:
The effect according to the invention consists in efficiently reducing the dead volume during the forming in the interior of the component in the case of large components. This is advantageously done by a in the hollow profile semi-finished product 1 introduced filling 2 accomplished. This requires a smaller amount of forming fluid in the short assembly times in the hollow profile semi-finished product 1 be initiated. This in turn means that much less pressurized forming fluid, such as precompressed gas, must be provided in pressure accumulators. As a result, this results in significantly lower energy expenditures over the entire process. The investment costs of the entire system are thereby reduced massively, since significantly less pressure accumulators and compressors are necessary. Also, the operating costs of production will fall significantly, on the one hand due to the reduced amount of gas required and on the other due to the reduced amounts of compressed air and electricity needed to operate the storage and compressors to compress the gas to around 1,200 bar. It is assumed that this technical measure can reduce the required energy by up to 70 percent.

The adjustment of the desired product properties does not necessarily have to be realized by the forming process, but is also possible in separate processes.

The main field of application is generally hydroforming / hydroforming of hollow sections and Hot Metal Gas Forming (HMGF) in particular. An application to the hydroforming / external high pressure sheet metal forming (IHB / AHB) is also possible with adaptation of the construction.

LIST OF REFERENCE NUMBERS

1

Hollow profile semifinished

2

 filling

3

 Tool for forming

4

 accumulator

Claims (6)

A method of pressure forming hollow sections with a forming fluid, comprising the steps of: a. Step A: Reduction of a volume that can be absorbed by the forming fluid within a hollow profile semifinished product ( 1 ). b. Step B: heating of the hollow profile semifinished product ( 1 ). c. Step C: Forming the heated hollow profile semifinished product ( 1 ) by the pressurized forming fluid. A method according to claim 1, characterized in that step A comprises at least one of the following substeps: a. Step A1: providing the hollow profile semi-finished product, for example made of metal, in particular steel or aluminum, preferably in the form of a tube extending along a straight and / or curved tube axis, wherein the tube preferably has one or two open ends, wherein the Pipe particularly preferably over at least a portion along the tube axis or along the entire tube axis has a constant cross-section. b. Step A2: Bending and / or mechanical shaping of the hollow profile semi-finished product, preferably in the intended form of the final product. c. Step A3: Coating the hollow profile semi-finished product against scaling. d. Step A4: filling one, several, or all cavities of the hollow profile semi-finished product, preferably such that the cavity / cavities is / are partially or completely filled, preferably such that the forming fluid to be introduced to the inner wall / inner walls of the filled hollow profile semifinished product can work. e. Step A5: filling the hollow profile semifinished product with a loose filling material, which is preferably such that it automatically occupies the volume which can be absorbed by the forming fluid, wherein the loose filling material is preferably selected from a group of filling materials, comprising: bulk material, for example sand, in particular temperature-resistant quartz sand, or pearls, for example Zirkoniaperlen. f. Step A6: filling of the hollow profile semifinished product with a flexible and / or moldable and / or variable filling material, which is preferably such that it adapts to an inner contour of the hollow profile semifinished product when filling the hollow profile semifinished product, wherein the filling material is preferably selected from a group of filling materials, comprising: wire, in particular steel wire, high temperature resistant heating wire, a telescoping device such as a telescopic cylinder with a solid cylinder and at least one hollow cylinder movable with respect to the solid cylinder. G. Step A7: filling the hollow profile semifinished product with a solid filler, which is preferably adapted to an inner contour of the hollow profile semifinished product, wherein the solid filler material is preferably selected from a group of filling materials, comprising: rods, rods, mandrels. H. Step A8: filling the hollow profile semi-finished product with a heated and / or heated filling, so that the hollow profile semi-finished product at least a portion of or the total amount of heat required in the context of step B can be supplied via the filling. i. Step A9: Fixing the filling within the hollow profile semifinished product in order to prevent a movement of the filling with respect to the hollow profile semifinished product. j. Step A10: Closing one, several or all access openings of the filled hollow profile semifinished product, in order to prevent leakage of the filling from the hollow profile semifinished product. Method according to one of the preceding claims, characterized in that step B comprises one of the following sub-steps of at least: a. Step B1: heating of the hollow profile semi-finished product by induction, conduction, contact heating or in the oven. b. Step B2: heating the hollow profile semi-finished product to an austenitizing temperature or solution annealing temperature. c. Step B3: Heating of the hollow profile semi-finished product to a working temperature in the range of 500 to 1100 ° C, preferably 550 to 1100 ° C. Method according to one of the preceding claims, characterized in that step C comprises at least one of the following substeps: a. Step C1: introducing the filled and heated hollow profile semi-finished product into a tool for forming, preferably by an automatic handling. b. Step C2: Closing of the tool and / or sealing of the hollow profile semi-finished product, preferably by one or more sealing units, wherein the one or more sealing units preferably closes / close one or more access openings of the hollow profile semifinished product. c. Step C3: Provide a gaseous forming fluid, preferably air, nitrogen or argon. d. Step C4: Provision of a pressurized forming fluid outside the hollow profile semifinished product, preferably in an accumulator, preferably at working pressure. e. Step C5: introducing the pressurized forming fluid into the hollow profile semi-finished product, preferably by transferring the forming fluid from a pressure accumulator. f. Step C6: increasing the pressure within the hollow profile semifinished product with a pressure build-up rate in the range of 10 to 1000 bar per second, preferably in the range of 500 to 1000 bar per second, more preferably in the range of 800 to 1000 bar per second. G. Step C7: increasing the pressure within the hollow profile semi-finished product to a working pressure, wherein the working pressure is preferably in the range of 1 to 1200 bar, preferably in the range of 100 to 1200 bar, particularly preferably in the range of 300 to 1200 bar. H. Step C8: Filtration of the forming fluid during deflation from the hollow section semifinished product after conversion to separate filling and forming fluid from each other. i. Step C9: Remove the filling from the formed hollow profile, preferably in the cooled state. Method according to one of the preceding claims, characterized in that the steps A to C in cycle times of up to 60 seconds, preferably up to 45 seconds, preferably repeated up to 30 or 20 seconds. Apparatus for pressure forming of hollow profiles according to the method according to any one of the preceding claims.

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