EXTRUDED PROFILE PRODUCED WITH ROTATING SHAPING DIES
A device and method for designing lightweight, strong, material efficient, extruded and pultruded profiles, profile segments and surfaces produced in profile production with rotating dies creating superior resistance to compression, bending and buckling, higher energy absorption and right strength in the right place, by: varying the thickness along and across the direction of extrusion, making reinforcing patterns varying the profile thickness, and in some cases varying angles and patterns which increases the profile segments/surface resistance against compression, bending and buckling relative to the amount of material used and resulting in the manufacturing of optimized beams and surfaces that have superior properties in terms of strength/weight, stiffness/weight ratio, mechanical energy absorption/weight unit, deformation and natural frequency, thermal transfer capacity, the breaking of the laminar flow, increased/optimized surface for chemical and/or electrochemical reaction etc.
The present invention relates to a new principle to design profiles, profile segments, beams, elements for absorption of kinetic energy and surfaces/panels by varying the wall thickness along (_t)+across extrusion or pultrusions direction, making reinforcing patterns (2, 3), vary the profile thickness (T, t), and in some cases vary, cross-sectional area (_A
The invention can be done in various forms in a number of different ways for different applications, with various requirements and is applicable to extrusion and pultrusion of plastically deformable materials and material combinations for example metal, metal composite, plastic, plastic composite, wood based composites, clay, rubber or reinforced rubber formed to profile by a process comprising a tool with one or more fixed parts partially predefining the profile's appearance/cross section before the profiles final shape is defined to a fixed or varied cross section when the material passes rotating body can be patterned or smooth and whose position in some embodiments of the invention may vary relative to other bearing surfaces or rotating bearing surfaces in the tool with which they define profiles final shape, whether rotating dies used are patterned or not.
BACKGROUNDWith an increasingly stronger need to economize on energy and raw materials, the value of saving on weight in cars, trucks, buses, boats, trains, and not least in airplanes is increasingly actualized.
Materials such as fibre composites, aluminum, aluminum composites, high strength steel etc. have made their entry into the designs traditionally based on steel/iron in the quest to keep the weight down, while requirements for performance, strength, environmental aspects, recycling and safety is increased for each product generation.
Consequently, the value of a kilogram of weightsaving is increased for every year and, of course, this figure varies for boats, cars, buses, trucks, and airplanes.
And commodity prices of light metals, such as aluminum, magnesium, titanium etc. has risen with demand and energy prices, resulting in a quest to minimize unnecessary use of materials in all kinds of beams, profiles and products.
This makes it increasingly important to use the materials in an optimal and “intelligently” way—to make sure the material is placed where it provides maximum desired strength and property and minimize or eliminate the amount of material where it is least useful.
This is because a profile with the same cross-section or appearance all the way often do not qualify for meeting customers product and application requirements regarding design, function and performance particularly in automotive, aerospace, mass transportation, and structural applications.
The traditional methods first manufacturing profiles and then process until varied thickness and/or pattern requires very high costs for processing and machining equipment, which is due cost reasons altogether would exclude processing developed optimized profiles. In addition, such machining result in broken material veining (generating fractural indication weaknesses).
SUMMARY OF INVENTIONAn object of the example embodiments of the disclosure is to provide an improved extruded profile. This object is partly achieved by the features of the independent claims.
According to one example embodiment, there is provided an extruded profile having a longitudinal direction X and a transverse direction Y, and manufactured by dynamic extrusion/pultrusion of plastically/thermally deformable material with one or more static array elements with static bearing surfaces which in cooperation with one or more rotating dies whose rotating bearing surfaces completely or partly defines a profile cross-sectional shape that comprises two different thickness values in a longitudinal cross-section and/or a transverse cross-section.
In other words, the profile cross-sectional shape comprises at least two different thickness values in the longitudinal cross-section. In addition, or alternatively, the profile cross-sectional shape comprises at least two different thickness values in the transverse cross-section.
As mentioned herein, further advantages are achieved by implementing one or several of the features of the dependent claims.
By way of example, the difference between a maximum thickness value and a minimum thickness value for at least one cross sectional shape is in the range between 2%-80%. In another example, the difference between a maximum thickness value and a minimum thickness value for at least one cross section is in the range between 4%-50%. In yet another example, the difference between a maximum thickness value and a minimum thickness value for at least one cross section is in the range between 5%-20%.
Typically, the thickness, as seen in the vertical direction Z, is varied for a given width along the transverse direction Y for any transverse cross-section.
In addition, or alternatively, the thickness, as seen in the vertical direction Z, is varied for a given length along the longitudinal direction X for any longitudinal cross-section.
According to one example embodiment, the shape of the transverse cross section is varied for a given length along the longitudinal direction X.
According to one example embodiment, a variation of the thickness for a given width is any one of a linear variation, non-linear variation, and step-wise variation. Other variations are also conceivable depending on the use and installation of the profile.
According to one example embodiment, the profile cross-sectional shape defines a pattern extending in a direction different than the longitudinal direction and the transverse direction.
Typically, although not strictly required, the pattern comprises at least one indentation and at least one projecting region.
According to one example embodiment, the pattern is part of a repetitive pattern extending in the directions of the profile.
By way of example, the at least one reinforced region is at least partly or entirely a diagonal-extending region, a polygon-shaped region such as a circular-shaped region, an elliptic-shaped region, a triangular-shaped region or the like, as seen in the longitudinal direction and in the transverse direction.
According to one example embodiment, the profile comprising at least two different transverse cross sectional shapes along the longitudinal direction X, and at least two different longitudinal sectional shapes along the transverse direction Y.
Typically, the difference between said at least two different thickness values is provided by a variation of the profile thickness in the profile longitudinal direction.
An extruded profile according to the example embodiments as mentioned herein is particularly useful as a vehicle structure profile. By way of example, the profile can be used as an impact beam, impact absorbing beam or the like, such as a bumper impact beam. However, the extruded profile can be used and installed in several different types of structures and systems.
The term “pattern” as used herein may refer to any type of region defined (or obtained) by the dynamic extrusion/pultrusion method as mentioned above, which typically at least partly or entirely defines a profile cross-sectional shape that comprises two different thickness values in a longitudinal cross-section and/or in a transverse cross-section.
It is to be noted that the pattern may sometimes also be referred to as a reinforced region, a reinforced pattern, stiffening pattern, stiffeners, pattern segment or segment, or simply as a pattern.
Typically, although strictly not necessary, the pattern comprises at least one indentation and at least one projecting area.
The material veining obtained during profile creation with rotating dies instead follow the surface of the finished product , resulting in several positive effects:
1. No broken materials veining.
2. Reduced risk of so-called “desquamation” or scaling that occur as a result of friction-temperature extrusion speed because of tensile stresses exceed exceeding the materials 5 tensile strength at the corresponding temperature. Thanks to the lower friction forces in the profiles surface layer occurs radically lower tensile stresses in the profile surface, enabling extrusion in higher speeds without the risk that transverse cracks occurs (ref. scaling “Plastic processing” by Erik Storm, p. 128 publishers Bonniers).
3. Extruded/pultruded materials often have a 15 better material property (higher strength) in the utmost millimeters of the surface and consequently it always results in maximum material performance in the surface.
4. Homogenous material/product characteristics. At regular extrusion/pultrusion, the material gets better strength along the extrusion/pultrusion direction than it gets in the transverse direction, which inhibits product performance. In a profile extruded/pultrudeded with rotary shaping die members the material get more isotropic properties regarding strength and direction.
5. Composites and specially metal composites reinforced with ceramic fibers or powder, can be very difficult to machine and with eliminated or minimized machining the problem decreases.
6. The composite fibers and/or powder settles according material veining and thus provide maximum performance in the desired direction.
By in accordance with the invention utilising rotational shaping members, placing the material on the right place one can achieve optimized profiles, beams and beam segments thus can be made to achieve the desired strength, stiffness, resilience, flexibility, natural frequency, compression resistance and kinetic energy absorption with minimal weight/material consumption.
This applies also to design of products so that they give best possible “crash-management” i.e. is strong on the right place and weak in the right place, so that it can achieve desired deformation order in a beam, which is made possible by making the profiles with different strengths in different places, and that the components are deformed with linear or progressive force to get steady deceleration in the example of a car collision or an aircraft crash, so that the parts are deformed in the desired manner in the right order and absorbs as much kinetic energy as possible, in a manner that protects passengers from unnecessary forces and injuries.
This makes the methodology described in this document particularly useful for bumpers, crash-box (the component that secures the bumper and that absorb kinetic energy in collisions at a certain speed).
The methodology is also useful for optimizing the lamp-posts, sign holders and other elements in the traffic environments, as well as all profiles and beams that are included in some form of load cases.
The method makes it possible to extract the materials and weight saving potential that profile production with rotating dies give after the last development stages and innovations:
The new methodology for the process described in Swedish Patent Application No. 0702659-4 (Apparatus and procedure to start up, control of outgoing material and Process Stabilization in profile manufacturing with rotating dies) by Garry Leil describing how to solve the problems that hindered the industrialization of profile production with rotating dies.
The principle of profile creation with rotating dies have been previously described in various papers and patents and developed in a number of steps including Pierre Hamel (Technical Paper “How to extrude embossed flexible profiles” by Pierre Hamel in Plastics Engineering 15, band 36, No. 6, June 1980 p. 34-35) and the current inventor (pat. SE504300 (C2) and Pat. SE514815 (C2).
Both patent SE504300 (C2) and the patent SE514815 (C2) may be said to describe the procedure for extrusion with rotating dies acc. Pierre Hamel instructions, while patent applications 0702030-8 and 0702659-4 describes new methods and approaches enabling and in some cases is a prerequisite for producing the profiles described in this patent. Production with rotating dies members are possible in all types of pultrusion and extrusion plants, with minimal or no adaptation needs of the facility, including hydraulic metal extrusion lines, screw extruders for rubber/plastic, conformextrusions machines and pultrusion machines, meaning that there is much good industrial capacity built to produce optimized profiles, segments and surfaces designed according to the methodology of the present invention.
As mentioned above, the purpose of the invention is to by optimized design, rationally reduce weight, raw material consumption, energy consumption and emissions in the stage of manufacturing and use the profiles, beams, beam segments and areas having property improving designs and/or thickness variations that utilize the capabilities of rotating dies in a way that conventionally designed profiles, beams and surfaces can not make. This makes it possible to:
1. Get a profile or surface with improved weight/strength ratio=save weight+raw materials.
2. Customize properties.
3. Replace more expensive materials such as e.g. carbon fibre and titanium with aluminum and magnesium (thanks improved better strength/weight relation.)
4. Reduce processing costs and material waste.
5. Improve crash protection in vehicles.
6. Achieve components with improved performance regarding acoustics/vibration.
7. Achieve greater thermal transfer capacity through micro and macro-patterning of profiles.
7. Achieve higher/optimized surface for chemical and/or electrochemical reaction.
The invention relates to a new way to design, lighter, stronger, stiffer material efficient profiles (6,26,) Surfaces (22), beam segments (4), and energy absorbing members (6) and structures (23), with the desired behaviour patterns (7
Different embodiments and applications of the invention, makes it possible to improve the weight/strength ratio up to and in some cases over 50% in actual components with equal or better performance and with optimized characteristics (for example. deformation behaviour, natural frequency, etc.), enabling it to make better and more fuel-efficient cars, vehicles, airplanes, boats, with maintained safety and stronger structures that are lighter and less expensive.
Explanations of context, nomenclature and used words in patent:
Optimized profile With optimized profile it is meant a profile manufactured with dynamic extrusion or pultrusion manufactured with reinforcing patterns (18, 19, 20, 21) and/or goods variation (_t, _A) that gives the optimized profile a higher strength/weight ratio than a corresponding profile with the same amount of material and cross layout without reinforcing patterns and goods variation has. The patterns of the optimized profile can be customized to achieve maximum strength, stiffness, ability to absorb kinetic energy, be resistant to buckling, compression, have different properties in different directions etc.
Optimized surface: With optimized surface it is mean an essentially flat profile (see
1. Dies (see
2. If the volumes are low and you want to have patterns on the inside of the profile, it is much easier and cheaper to make a tool with a rotating shaping member (
3. If you want optimizing pattern around all sides of for example a rectangular profile it will be very difficult to make a profile creating die with four rotating dies that shall be able to cope with the forces when extruding for example aluminum in long batches. If pattern on the inside and outside around, the only option is to use an optimized surface with pattern on both sides (see
Extrusion
Procedure in which a material under pressure is pressed through a profile shaping tool (also called die) with hole(s) that defines the outgoing materials cross-section and appearance. Extrusion can be performed in most metals, metal matrix, thermal resins, some fibre composite mixtures, ceramics, clay, rubber, candy, food (e.g. pasta, etc.).
Pultrusion
In contrast to the extrusion means the profile drawing. Pultrusion generally means that a continuous fibre bundle impregnated with liquid resin drawn through a heated die, but pultrusion is also used for shaping metal tubes and profiles. Resin impregnation occurs in a resin bath. The most common material is glass-reinforced unsaturated polyester. Other core epoxy resins and PolyUrethane are used depending on the application. Often used fibrous material in the form of woven or felt fabric, resulting fibre beam to achieve strength in the transverse direction. Pre-preg fibres (Fibres that are pre-impregnated with resin), can also be used.
Dynamic Extrusion
Procedure in which a material under pressure, is pressed through a tool/die with rotating forming members/dies that can give the profile a varied cross-section and/or appearance in the form of e.g. patterns on one or more surfaces and dimensional changes in cross-sectional area and or goods thicknesses. The rotating shaping die members can be with pattern/variation as well as smooth or a combination of both. The rotating shaping die members can be raised and lowered independently of other cycles in the process.
Dynamic Pultrusion:
Procedure whereby one/several profile(s) drawn through a die/tool with rotating forming members/dies that can give the profile(s) a varied cross-section and/or appearance in the form of e.g. patterns on one or more surfaces and dimensional changes in cross-sectional area and or goods thicknesses. The rotating shaping die members can be with pattern/variation as well as smooth or a combination of both. The rotating shaping die members can be raised and lowered independently of other cycles in the process.
Die: Generally, the name used by professionals for profile production tools.
Rotating die: Rotating profile-shaping member/organ of the tool for dynamic extrusion/pultrusion
Process collapse/breakdown: Generic name for the failure of the start up of extrusion/pultrusion or problems at billet exchange, production, etc. that results in production stop. The high proportion of process-breakdowns has made the industrialization of the production of profile with rotating dies very problematic.
Pressure drop: Reduction of pressure by the tool is a result of area-reduction, plastic exemplary work and friction. At metal extrusion converted large amounts of energy to heat, as a result of pressure. By “pressure drop balancing”—making adjustments to the pressure drop in the tool, the outgoing material get the same speed in all parts.
Flow imbalance: Imbalance means that the outgoing material will or want to come out with higher or lower speed at certain parts of the profile cross-section. A profile extruded in a tool with the imbalance may be less resistant (due to internal tensions), tend to dent or bend and at the extrusion with rotating dies result is often the process breakdown.
Bearing Surface: The surface of an extrusion die in the smallest cross section that the extruded material is forced through under pressure and thus constitutes the surface to finally define the profile cross-section and appearance.
Static Bearing Surface: A bearing surface the extruded material is forced to pass at a relative speed of outgoing profile speed, because it is static, so that means there is a speed difference between the static bearing surface and the extruded material, resulting in a lot of friction and heat. By regulating the length of the bearing surfaces can regulate the total amount friction and thus the pressure and speed of the outgoing material.
Rotating Bearing Surface/Rotating profile shaping surface: A rotating bearing surface is a surface of the rotating die/member that defines the profile cross-section, making patterns possible as well as wall-thickness variation. A rotating bearing surface in general generates much less resistance/friction against the flowing material than a static bearing surface, which previously has created major problems with the imbalance between the different parts of the profile cross-section, which is defined by the rotating bearing surfaces and the parts that are defined by static bearing surfaces. This has often resulted in the process breakdown at start up. At profile manufacturing with use of present inventions device and method the problems with this, is radically reduced, through the gripping, steering and pulling of the profile in the right direction already in the tool. If you lift the rotating bearing surfaces at start up and let the gripping, steering puller go into the tool, elimination of deviating profile that can cause process failure is achieved.
Pre-Bearing/Pre-Bearing Surface: The surface area that the extruded material passes just before it comes to the rotating die/forming member and its rotating bearing. The pre-bearing brings down the material cross section so much so that the subsequent rotating die wont have to take up unnecessarily large forces from the extruded material. Pre-bearing has in combination with preceding shape in the die upstream a central role for control and/or redulation of material flows through the die.
Puller/Profile Puller: At the extrusion of metal profiles, it is customary that when one has squeezed out enough profile to reach the ordinary puller (usually 3-7 meters from the die) to stop extrusion, grip profile and then pull the profile and then re-start the extrusion. Some modern plants use dual-pullers, which means increased productivity and reduction of the number of stops and downtime.
Griping & steering pulling device In order to be able to make a plurality of the profiles shown in the drawings, it requires a special device a so called gripping & steering puller and procedure shown in the patent application 0702659-4. The gripping steering pulling device, grip, steer and pull the profile long before ordinary puller, which is too far from the die since the majority of the profiles exhibited here requires direct control and stretching after or before leaving the tool. In some cases, the gripping, steering puller go all the way into the tool and grip and pull the material before it leaves the die (see
Griping puller can eliminate or minimize process breakdowns and enable start-up and ongoing efficient production of extruded profiles with rotating dies, which would otherwise be unthinkable due several factors:
I the adhesion between the rotating bearing and extruded material.
II friction difference between the braking friction of rotating bearings and static bearings (rotating bearings brakes far less than static bearings).
III absence/lack of static bearings that give directional control to outgoing profile (rotating bearings have a radius and are consequently, not so good at steering the profile straight, they tend to steer the profile to follow the rotating bearing radius, if the adhesion between the rotating bearing and outgoing material occurs).
IV low intrinsic stiffness, thin profile,
V deep patterns relative wall thickness and steep angles on the patterns.
In varying cross sectional area.
The present invention enables a variation of the thickness and tread depth, in reality, by taking into account factors such as variation of the pressure drop and the outlet rate, both of which vary when varying the outlet area/cross section of the profile:
A reduced outlet area=increased pressure drop and at constant speed on the feeding of material into the extrusion/pultrusiondie the result is a higher outlet speed and potentially big problems with increased temperatures and intermittently varying outlet speed of profile: for example, a halved outlet area result in doubled outlet speed at continuous feeding of extrusion material, which more or less inevitably leads to large process problems with varying quality on the basis profile and is likely to result in process breakdown. This is because the outbound profile must rapidly accelerate and decelerate, giving very large varied loads between back pressure and tension loads of outgoing material directly on the tool's outlet after the die bearings, where the material is at its warmest and softest and most dependent on a continuous stretch/steering—resulting in that the profile easily lose control and stick to the rotating die and plugs the tool outlet, the process of breakdown is a fact.
Another aspect is the dependence between the maximum extrusion and cross-sectional area of a profile and the thickness of the profile extruded/pultruded, which is particularly sensitive in ingot fed extrusion lines is the so-called extrusion ratio very crucial (extrusion ratio=the materials area from ingots in relation to the outgoing profile area). A high extrusion ratio reduces the maximum discharge rate of extruded/pultruded profile due to, among other things heat build up and flaking. Flaking is a phenomenon that occurs when you try to extrude/pultrude in high speed and outgoing profile has problem with holding together, due to the forces of friction between the outgoing profile and bearing surfaces and area reduction, is exceeding or approaching outgoing materials maximum speed and cracks which generally goes across extrusion/pultrusion direction. An increased area reduction results in other words, in increase of the risk of scaling, while speed is increased on the output profile, if one does not take this into account. In other words, feeding material into the extrusion/pultrusion tool result in the profile goes faster when there is a reduced cross-sectional area (as it would be wise to rather have a reduced exit speed to avoid cracking, flaking and/or overheating of outgoing material. This is solved, according to the present invention, by varying the speed/volume per unit time of material feeding extrusion/pultrusion die in order to either allow such constant outlet speed as possible on the outgoing profile, or decreases the exit speed, to avoid risk of flaking/overheating of outgoing material, when the smaller profile area is run.
Naturally, this includes synchronizing of puller device that holds the profile tensioned. The application of the present invention is applicable to all types of extrusion plants, with minimal or no adaptation needs of the facility, including hydraulic facilities metal extrusion, screw extruders for rubber/plastic and conformextrusions facilities, etc.
With reference to the appended drawings, below follows a more detailed description of embodiments of the disclosure cited as examples.
In the drawings:
The present invention will in the following be described in various embodiments with reference to the accompanying drawings which of example show preferred embodiments of the invention, the invention is not limited to those in the drawings and descriptions exemplary embodiments, but
can by a technician be performed in other ways and with more combinations based on the description and appended claims with variations of profiles, profile segments and surfaces with varied patterns and thicknesses and profile segments and profiles with different configurations that look different from those in the exemplifying drawings on exhibited examples. The invention is comprised of all the possible combinations which can be achieved within the patent claims.
As illustrated in the figures herein, for example
The extruded profile has a longitudinal direction X, a transverse direction Y and a vertical direction Z.
The extruded profile is manufactured by dynamic extrusion/pultrusion of plastically/thermally deformable material with one or more static array elements with static bearing surfaces which in cooperation with one or more rotating dies whose rotating bearing surfaces completely or partly defines a profile cross-section, in particular a cross-sectional shape.
The figures illustrate an extruded profile having a profile cross-sectional shape that comprises two different thickness values in a longitudinal cross-section and two different thickness values in a transverse cross-section. However, it is to be noted that the extruded profile may only have a profile cross-sectional shape that comprises two different thickness values in the longitudinal cross-section. Alternatively, the extruded profile may only have a profile cross-sectional shape that comprises two different thickness values in the transverse cross-section.
In addition, it is to be noted that the cross-sectional shape may of course include any other number of different thickness values. Thus, it is only required that the profile cross-sectional shape comprises at least two different thickness values in the longitudinal cross-section and/or at least two different thickness values in the transverse cross-section. That the extruded profile has a profile cross-sectional shape that comprises at least two different thickness values in the longitudinal cross-section and at least two different thickness values in the transverse cross-section can be readily appreciated from the various figures, showing e.g. a linearly varied thickness of the cross sectional shape, a non-linearly varied thickness of the cross sectional shape or a multiple step-wise varied thickness of the cross sectional shape.
Turning again to
Turning again to
By way of example, the difference between a maximum thickness value Tmax and a minimum thickness value Tmin in a cross-sectional shape is in the range between 2%-80%. In another example, the difference between a maximum thickness value and a minimum thickness value for at least one cross section is in the range between 4%-50%. In yet another example, the difference between a maximum thickness value and a minimum thickness value for at least one cross section is in the range between 5%-20%.
Further, as shown in figure la, the thickness, as seen in the vertical direction Z, is varied for a given width Ly. In this example, the variation of the thickness is varied in step-wise fashion. However, the thickness can be varied in several different ways. That is, a variation of the thickness for a given width can be any one of a linear variation, non-linear variation, and/or step-wise variation. Other variations are also conceivable depending on the use and installation of the profile, which are further illustrated by the figures hereinafter.
Analogously, as shown in
In some design options, as shown in various figures herein, the thickness, as seen in the vertical direction Z, is varied for a given width Ly along the transverse direction Y for any transverse cross section.
According to one example embodiment, the shape of the transverse cross section is varied for a given length along the longitudinal direction X.
Turning again to e.g.
Typically, although not strictly required, the pattern comprises at least one indentation and at least one projecting region.
According to one example embodiment, the pattern is part of a repetitive pattern extending in the directions X, Y and Z of the profile, see e.g.
By way of example, the pattern is at least partly or entirely a diagonal-extending region (see
According to one example embodiment, the profile comprising at least two different transverse cross sectional shapes along the longitudinal direction X, and at least two different longitudinal sectional shapes along the transverse direction Y, which may be gleaned from
In addition, or alternatively, the difference between the at least two different thickness values T1 and T2 is provided by a variation of the profile thickness in the profile longitudinal direction X.
As illustrated in the various figures herein, the variation in thickness can also be varied in both the transverse direction Y and the longitudinal direction X.
In the following description in conjunction with the
This beam segment gets a slightly “softer” characteristic in compression by the circular reinforcements than beam in
When joining multiple segments, Friction Stir Welding is an appropriate method, since it provides joint without tensions or weakening defects in material micro-structure, including materials with extremely small crystalline in the size of 1μ able to maintain their properties relatively intact at FSW. Through additionally process removing material (24) which is not maximum effective for segment strength, you can at an extra cost achieve further improved strength/weight ratio of beams and segments that don't need to be covered. This processing may conveniently be done by water jet, which is relatively inexpensive, efficient and do not produce changes in the structure of materials from heat generation or tools or contamination cracking from vibration and cutting forces.
To succeed with an extruded or pultruded so called truss segment or truss profile, you should take attention to creating a cross-sectional area (here exemplified with cut marks 25A, 25B, 25C and 25D) transverse profile that is substantially the same in pattern cycle (one revolution of the rotating shaping device/die) so that the profile strive to get out of uniform speed of extrusion/pultrusion tool. If the variations on outgoing cross-sectional area big and quickly arise a pulsation in a metal extrusion line could mean that every billet
That is why it advisable to if the end product is a very optimized beam segment or profile, so that the end result is a profile with fast, cyclical, diversified, cross-sectional area variations to making the areas of compensation of the areas to be machined away (24), so that the extrusion/pultrusion has a process in terms of simple profile to do with the relatively even cross sectional area along the profile, which works well in process and allows for greater variety in material thickness (_t). Then, when the area-compensating areas (24) is machined away, it is a very light, strong and rigid profile/segment that have good quality and can be produced with a low proportion of scrap and low bearbetnigs costs.
In
In
In
In
This provides a profile which has very special properties: it is flexible and weak to bending, while being very stiff and resistant to compression crosswise.
In
In
In order to obtain optimal material performance and as little scrapping as possible, it is advisable to avoid stopping for a re gripping of profile, this is achieved according to
Gripper-puller (230C) has released profile and moved in sideways before the next startup or before billet exchange where it can ensure that the profile is stretched-drawn at cutting of extrusion lines that lack dual ordinary pullers.
By the thickness varied over profile/beam segments length, regardless of the rotating shaping cycle entities (which consist of a rotation), so you get maximum strength on the part of beam/the profile which is subjected to the greatest loads.
This is achieved by the/the rotating shaping units (110
The disclosure also covers all conceivable combinations of the described aspects, variants, alternatives and example embodiments of the disclosure.
Furthermore, the disclosure is not limited to the aforesaid aspects or examples, but is naturally applicable to other aspects and example embodiments within the scope of the following claims.
Claims
1. A tool configured to form, by dynamic extrusion or pultrusion of a plastically and/or thermally deformable material, a profile having a longitudinal direction and a transverse direction, the tool comprising:
- one or more static array elements having static bearing surfaces; and
- one or more rotating dies having rotating bearing surfaces,
- wherein the static bearing surfaces and the rotating bearing surfaces cooperate to define a cross-sectional shape of the profile, and
- wherein each of the rotating bearing surfaces has a bearing profile that is configured to provide the profile with two different thickness values in the longitudinal direction and in the transverse direction.
2. The tool according to claim 1, wherein the tool is configured to provide the profile with a variable thickness in a vertical direction for a given width along the transverse direction for any transverse cross section of said profile.
3. The tool according to claim 1, wherein the tool is configured to provide the profile with a shape of a transverse cross section that is varied for a given length along said longitudinal direction.
4. The tool according to claim 1, wherein the difference between said at least two different thickness values is provided by a variation of the profile thickness in the longitudinal direction of the profile.
5. The tool according to claim 1, further comprising means for varying the location of the rotary bearing surfaces to provide the profile with sections having different cross-sectional areas.
6. The tool according to claim 1, further comprising means for varying the position of the static bearing surfaces to provide the profile with sections having different cross-sectional areas.
7. The tool according to claim 1, wherein the rotating dies can be raised or lowered during operation of the tool.
8. The tool according to claim 1, wherein the tool is configured to provide the profile with profile segments extending in a direction different than the longitudinal direction and the transverse direction.
9. The tool according to claim 8, wherein the profile has variation of 2 sides of the profile segments.
10. The tool according to claim 8, wherein several profile segments have variation.
11. The tool according to claim 1, wherein the tool is configured to provide the profile with a planar profile surface with variation and that is bent to a desired shape.
12. The tool according to claim 1, wherein the tool is configured to provide the profile with a flat profile surface with variations on both sides and that is bent to a desired shape.
13. The tool according to claim 1, wherein the one or more rotating dies comprise two similar rotating dies on each side of the plastically and/or thermally deformable material so as to provide the profile with a uniform cross-sectional area.
14. The tool according to claim 1, further comprising one or more movable bearing inserts.
15. The tool according to claim 14, further comprising a pre-bearing configured to align with and form an extension to a bearing when the one or more movable bearing inserts are in an outer position, so that a bearing length increases when a thickness of the profile thickness increases.
16. The tool according to claim 15, wherein the one or more rotating dies are raiseable or lowerable, and wherein the pre-bearing is raiseable or lowerable.
17. The tool according to claim 1, wherein the tool is configured to vary a speed and/or volume per time unit with which an input amount of material is fed to the tool so as to provide a constant outlet speed as possible on the output profile, or decrease a discharge rate, to avoid risk of flaking and/or overheating of outgoing material, when a smaller profile area is run, thereby synchronizing the input amount of material with an amount of material necessary to vary outgoing cross-sectional area and thickness of the profile.
18. The tool according to claim 1, wherein said profile is any one of a vehicle structure profile or an impact absorbing beam.
19. The tool according to claim 1, wherein the bearing profile comprises a surface pattern or a varied radius.
20. The tool according to claim 19, wherein the surface pattern forms a repetitive profile pattern extending in the longitudinal direction of the profile.
Type: Application
Filed: Feb 19, 2021
Publication Date: Aug 12, 2021
Inventor: Mark Jansson Kragh (Varberg)
Application Number: 17/180,278