This invention concerns a holding device according to the preamble to claim 1 for holding an item in connection with hardening of the item.
The invention also encompasses a method for hardening together an item according to the preamble to claim 7.
The fabrication of many items and structural elements, such as vehicles, vessels and aircraft, out of sheet metal or hardenable composite materials containing fibers, such as glass fibers or carbon fibers, is known. Such composite materials are distinguished by light strength and relatively low weight. These distinguishing properties have resulted in it becoming increasingly common in the aviation industry to use items containing composite materials. One often used type of item comprises a cell core and a beam frame which surrounds the cell core and consists of glued carbon fiber beams. The cell core, which is relatively pliant, must be glued at a low pressure, typically 180 kPa. On the other hand, a high pressure, typically 300-600 kPa, is prescribed when gluing the beams to the frame in order to produce a good glue joint.
The above-described item type thus requires that the beams first be glued together at the higher pressure, and that the cell core then be glued at the lower pressure. A tool that can be used when hardening items of this type is described in WO 01/47695.
One purpose of the invention is to reduce the costs and lead times associated with the assembly of said items and other items wherein the parts involved require hardening at different pressures.
This purpose has been achieved according to an embodiment of the invention by means of a holder for holding an item in connection with the hardening of same in a pressure tank that has a pressure that is elevated in relation to the atmospheric pressure. The holding device comprises one or more support elements that entirely or partly surround the lateral surfaces of the item and are arranged so as to support the item during hardening, and to exert a differentiated pressure on the item.
In a preferred embodiment at least one of the support elements is arranged in relation to the item in such a way that the support element exerts, along its length, different levels of pressure on the item in that, in a first region along its length, the support element presses against the item with a pressure that is elevated relative to the pressure-tank pressure and, in a second region along its length, presses against the item with a pressure that is lower relative to the pressure tank pressure. The support element that exerts, along its length, different levels of pressure on the item can be fixedly arranged in the holding device with a pivot point chosen so that the support element exerts the elevated pressure in the first region and the lower pressure in the second region. The support elements that do not exert different levels of pressure on the item lie in abutment with the item along their entire length essentially without pressing against the item.
In a special embodiment the holding device is arranged so as to hold all item comprising a core and a beam frame that surrounds the lateral surfaces of a core and includes at least two beams for gluing of the core to the beam frame and gluing of the beams to one another. The support elements are then arranged so as to exert the differentiated pressure so that they press the beams toward one another at the elevated pressure relative to the pressure-tank pressure, and lie in abutment to the item essentially without exerting any pressure thereon where the core is to be glued to the beam frame. The elevated pressure pressing the beams toward one another is, e.g. roughly 2-4 times higher than the prevailing pressure in the pressure tank.
The invention also concerns a method for hardening together an item containing at least a core and a beam frame surrounding a core and including at least two beams whereby the core is glued to the beam frame and the beams of the beam frame are glued to one another. The method is characterized in that the unhardened item is arranged on a underlayer, that support elements are applied around the item to hold it together, that the support elements are caused to exert a differentiated pressure on the item, and that the unhardened item, on its underlayer and with the support elements, is introduced into a pressure tank for hardening. The support elements are caused to exert a pressure that is elevated relative to the pressure-tank pressure on the surfaces that press the beams together toward one another and lie in abutment to the item essentially without exerting pressure on the surfaces where the beams are glued to the core.
The holding device and method for hardening together an item according to the invention make it substantially easier to glue together an item comprising a core glued on a beam frame of beams that are glued together. The core is pressure-sensitive, and can tolerate a very low pressure laterally, while it can withstand a pressure of on the order of 180 kPa from above. A significantly higher pressure, on the order of 300-600 kPa, is consequently prescribed for gluing together the beams, in order to obtain a good glue joint. Despite these contradictory requirements, the device and method according to the invention enable gluing of the item in a single step. The pressure in the pressure tank, which is thus on the order of a maximum of 180 kPa, presses from above against the beam frame and the core. The support means arranged around the item resist the pressure which would otherwise be exerted on the item laterally, except for on those surfaces where the pressure that is elevated relative to the pressure-tank pressure is prescribed. The support means exert the prescribed pressure on these surfaces. In the holding device and method according to the invention, the pressure-tank pressure is thus used to create a differentiated pressure on the item.
An intermediate element 2 is displaceably arranged on the bed surface of the base element 1, i.e. the intermediate element 2 rests loosely on the base element 1. An item to be fabricated is placed on top of the intermediate element 2. The intermediate element 2 forms a shaping element for the item 3, i.e. the intermediate element 2 forms a surface that has a shape that corresponds to a surface of the item 3 to be fabricated that is faces in opposition to the surface of the intermediate element. In the example shown, the intermediate element 2 is relatively thin in comparison with the base element 1, and can measure from 2 to 7 mm, e.g. between 4 and 5 mm. The intermediate element 2 can advantageously have an upper surface that is essentially parallel with a lower surface of the intermediate element. The upper bed surface of the base element 1 will then advantageously also have a shape that corresponds to the shape of a surface of the item 3 to be fabricated. The intermediate element 2 alternatively has an upper surface on which the item 3 to be fabricated rests, and a lower surface, whereupon these surfaces are not parallel. For example, the upper surface can have a concave shape while the lower surface is flat. In the embodiment shown in
The intermediate element 2 is made at least partly of a composite material containing, e.g. fibers and a plastic material. Such fibers can consist of, e.g. carbon fibers, glass fibers and/or other mineral fibers. The plastic material contains a hardenable plastic, such as epoxy plastic.
The holding device also includes support elements 4 that are fixable on the intermediate element 2. The support elements 4 together form a frame that supports the item 3 to be fabricated. The inner surface of the frame is thus defined by the contour of the peripheral surface of the item. The support elements 4 are fixable on the intermediate element 2 by means of connecting elements 6. The support elements 4 are thus secured only to the intermediate element 2. The connecting elements 6 comprise, e.g. a bolted joint with a bolt and a nut that is threaded on the bolt. The bolt extends through the intermediate element 2 and one of the support elements 4, and includes a bolt head that is countersunk into the intermediate element 2. Other connecting elements are also possible within the scope of the invention, e.g. a single non-threaded bolt that extends through a hole in the intermediate element 2 and one of the support elements 4 with a suitable fit. It is also possible to fasten one or several of the support elements 4 to the intermediate element 2 by means of a more permanent joint, e.g. by gluing. Each support element 4 has a support surface 10 that is turned toward the peripheral surface of the item 3 to be fabricated. The support surface 10 thus has a contour that corresponds to the peripheral contour of the item 3 to be fabricated. The mounting of the support elements 4 will be described in greater detail in connection with
The support elements 4 can also be made of a composite material containing fibers and a plastic material. The fibers can consist of, e.g. carbon fibers, glass fibers and/or several mineral fibers, and the plastic material can contain epoxy resin. The support elements 4 advantageously contain a higher proportion of plastic material than the intermediate element 2. The support elements 4 are suitably made using dies made of metal, such as aluminum or steel.
The holding device further contains means for carrying gas away from a region above the base element 1. These means comprise ducts 19, which have an opening 20 in the upper bed surface of the base element 1, and which extend to a pump 21. There is also an essentially leaktight cloth 22 above the upper bed surface of the base element 1. The cloth 22 is fastened along the periphery) of the base element 1 using some fastening means 23, such as, e.g. adhesive tape. The cloth 22 thus covers the openings 20, the intermediate element 2, the support elements 4 and the item 3 to be fabricated. When the pump 21 is started, the gas that is present between the cloth 22 and the base element 1 will be carried away and a vacuum will be created, whereupon the cloth 22 will seal tight onto the item 3 to be fabricated. It should be noted that additional elements can be arranged between the item 3 and the cloth 22; for example, a perforated plastic film (not shown) can be placed nearest the item 3, and a so-called tear-away cloth (not shown) can be placed between the item 3 and the cloth 22. In one embodiment, the holding device with its associated item 3 can be put into an autoclave for heat treatment.
In
The core 5 is glued into the beam frame 7. The core characteristically has a cellular structure, such as a honeycomb structure, whereby the weight of the item 3 can be kept at a low level. The core is characteristically pressure-sensitive. In an example with a phenol matrix/aramid fiber core, the core can tolerate an extremely low pressure laterally. The core can withstand exposure to a pressure on the order of 180 kPa from above.
In
The fabrication of the item 3 can proceed in, e.g. the following manner. The intermediate element 2 is placed on the base element 1. The core is then placed on the intermediate element 2. The unhardened carbon fiber beams are also placed around the periphery of the core. The support elements 4 are then applied around the core 5 and the beam frame 7 of the carbon fiber beams 8 in the manner described in connection with
The invention is not limited to the embodiments shown, but can be varied and modified within the framework of the claims that follow. It should be noted in particular that the items 3 that can be fabricated using the holding device can, in principle, be of any arbitrary shape, and are in no way limited to the shape presented in the specification and in the drawings.
Number | Date | Country | Kind |
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0202624-3 | Sep 2002 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE03/01354 | 9/1/2003 | WO | 3/4/2005 |