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EP0031412A1 - Ski construction element - Google Patents

Ski construction element Download PDF

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Publication number
EP0031412A1
EP0031412A1 EP80106440A EP80106440A EP0031412A1 EP 0031412 A1 EP0031412 A1 EP 0031412A1 EP 80106440 A EP80106440 A EP 80106440A EP 80106440 A EP80106440 A EP 80106440A EP 0031412 A1 EP0031412 A1 EP 0031412A1
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EP
European Patent Office
Prior art keywords
ski
laminate
adhesive
thermoplastic
film
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP80106440A
Other languages
German (de)
French (fr)
Inventor
Gustav Dr. Bihlmayer
Erich Dipl.Ing. Dr. Balder
Robert Grabner
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Patheon Austria GmbH and Co KG
Lentia GmbH
Original Assignee
Chemie Linz AG
Lentia GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Chemie Linz AG, Lentia GmbH filed Critical Chemie Linz AG
Publication of EP0031412A1 publication Critical patent/EP0031412A1/en
Withdrawn legal-status Critical Current

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Classifications

    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C5/00Skis or snowboards
    • A63C5/12Making thereof; Selection of particular materials

Definitions

  • the invention relates to ski components for use in a method for producing skis according to the so-called injection ski method.
  • skis are known.
  • injection process in which the individual ski components, namely the upper chord, lower chord, edges, tip protectors, etc. are inserted into a closed mold and the cavity between the upper and lower chord is foamed with foam, in particular with integral rigid polyurethane foam (DE-OS 20 54 952).
  • the skis produced in this way have the disadvantage that the preload height, which regulates the contact pressure of the ski when skiing by the weight of the runner, and which, in order to ensure optimum skiing properties, should remain as constant as possible, especially at different temperatures, also changes a change in the outside temperature changes very much.
  • the reason for this strong change in the preload height with a change in temperature is that the connection between glass fiber reinforced plastic (laminate) and thermoplastic film, be it on the lower flange, where the thermoplastic film serves as a tread surface, or on the upper flange, where the thermoplastic film, e.g. a ABS film, which serves as surface protection, either directly between the film and the laminating resin or via duromeric adhesives, i.e. in a rigid manner.
  • thermoplastic film or the core material As a result, every thermal movement of the thermoplastic film or the core material is included and transferred to the ski.
  • the laminate has a very low coefficient of thermal expansion, the thermoplastic film and foam core, however, have a much larger If the outside temperature changes, the pre-tension of the ski changes, and with it its skiing properties very strongly.
  • skis which have a different construction, namely the so-called sandwich construction, that is to say from a molded body which consists of a core made of wood, foam or the like and side walls made of ABS or other plastics, and the supporting upper chord above or below or lower chord and the steel edges arranged next to the lower chord as well as the tread covering, it is known not to directly connect the individual parts, which are placed in a mold in the correct order and glued to one another, but a layer made of an elastomer Place the material in between as tension compensation.
  • This intermediate layer is used wherever rigid parts, e.g. Core and top flange or core and bottom flange are to be connected.
  • this elastomeric intermediate layer can jointly connect both the steel edges and the supporting lower flange to the molded body of the ski.
  • the use of elastic or plastic polymers as a vibration-damping intermediate layer between the load-bearing aluminum lamella and the lower or upper edge of the steel or between the load-bearing aluminum lamella and a phenolic resin laminate plate as the side wall is known from AT-PS 351 416.
  • the material intended to form the intermediate layer is applied in the liquid state to the surface of at least one of the bodies to be bonded, hardened, provided with adhesive, and connected to the second body, thereby avoiding the application of adhesive on both sides.
  • the present invention accordingly relates to a ski component made of thermoplastic foils and fiber-reinforced, thermosetting plastics (laminates) for use in the method for producing skis by the injection method, characterized in that the laminate serving as the lower flange has a thermoplastic tread surface and / or as a top flange serving laminate with a thermoplastic covering is connected by an elastomeric adhesive with a layer thickness of 0.05 to 0.5 mm.
  • All elastomeric adhesives are suitable as adhesives; these are plastics with a glass transition temperature) 0 ° C. and a shear modulus in the range> 10 2 N / mm 2 between 20 ° C. and the respective decomposition temperature.
  • Polyurethanes are particularly suitable, preferably those based on hydroxyl-containing polyesters which are crosslinked by isocyanates.
  • the adhesives can be used in solvent-free form or dissolved in a suitable organic solvent, such as methylene chloride or methyl ethyl ketone. Application in solution is particularly advantageous, but in the case of a polyurethane adhesive it must be ensured that polyol and isocyanate do not react prematurely with one another.
  • the application can take place on one side on the laminate or on the thermoplastic or also on both parts to be bonded, the adhesive being applied discontinuously or continuously, by hand or advantageously using a doctor blade or casting machine.
  • the parts to be glued can be pretreated in the usual way before gluing.
  • a polyethylene film is usually pre-treated oxidatively, a GRP laminate is mostly sanded, while ABS is mostly used untreated.
  • connection takes place under heat and pressure in multi-stage presses, continuous presses, calenders or other suitable devices. If a polyurethane adhesive is used, this heat activation creates the elastomeric state from the mixture of polyol and isocyanate and thus the elastomeric adhesive.
  • the choice of the layer thickness of the elastomeric adhesive within the range of 0.05 to 0.5 mm according to the invention depends on the roughness of the surfaces to be bonded.
  • the layer thickness of the adhesive is preferably 0.1 to 0.15 mm.
  • the present method can also be used if a thin, printed intermediate layer is introduced between a thick, transparent thermoplastic film and the laminate. This is sometimes advantageous if the difficult printing of thick plates e.g. HDPE should be avoided by using a thin, transparent, e.g. with the help of rotary printing, printed film is placed between the laminate and the thick transparent film or plate. All three layers are then bonded in one operation; the thin intermediate layer can be surrounded on both sides or only on one side by elastomeric adhesive.
  • the adhesive was applied in a layer thickness of 0.05 mm each to the HD polyethylene and to the laminate, the parts to be bonded were combined and at a pressure of 6 bar, a temperature of 100 ° C and a pressing time of 10 sec.
  • a 0.6 mm thick film made of ABS was glued to a unidirectional laminate with the aid of an adhesive which is based on a linear polyester, has a hydroxyl content of approx. 1% and contains 10% by weight triphenylmethane-4,4 ', crosslinked triisocyanate 4 ".
  • the adhesive was thereby mm applied to the laminate in a layer thickness of 0.15, the parts to be bonded were combined and at a pressure of 10 bar, a temperature of 90 0 C and a pressing time of 12 sec pressed together.
  • the adhesive was applied in a layer thickness of 0.04 mm each to the HD polyethylene and the laminate, the parts to be glued were combined and at a pressure of 10 bar, a temperature of 110 ° C and a pressing time of 15 sec pressed together.
  • 1 cross-country ski was produced by foaming with rigid polyurethane integral foam (density 0.4 g / cm 3 ) from the ski components produced according to Examples 1, 2 and 3.
  • the bias level of the skis was at +15 0 C for 20 mm.
  • the leader height increased by 25% to 25 mm.
  • ski components were manufactured exactly as specified in Examples 1, 2 and 3, but the bonding was in each case carried out using a conventional duromer adhesive made from epoxy resin.
  • a cross-country ski was also made from the ski components thus manufactured, la, 2a and 3a, by foaming with rigid polyurethane integral foam (density 0.4 g / cm 3 ).
  • the bias level of the skis was at +15 0 C for 20 mm. When cooling to -25 ° C, the pretension height increased by 50% to 30 mm.

Landscapes

  • Laminated Bodies (AREA)
  • Adhesives Or Adhesive Processes (AREA)

Abstract

Ski construction elements for use in a process for producing skis according to the so-called injection ski process, in which the fibre-reinforced, thermoset plastics (laminates), serving as lower and/or upper layer, are bonded to one another by an elastomer adhesive. Skis produced with the aid of such ski construction elements display only little change in their prestress under temperature changes.

Description

Die Erfindung betrifft Skibauteile zur Verwendung in einem Verfahren zur Herstellung von Skiern nach dem sogenannten Injektionsskiverfahren.The invention relates to ski components for use in a method for producing skis according to the so-called injection ski method.

Es sind verschiedene Verfahren zur Herstellung von Skiern bekannt. Eines davon ist das sogenannte Injektionsverfahren, bei dem die einzelnen Skibauteile, nämlich Obergurt, Untergurt, Kanten, Spitzenschoner usw. in eine geschlossene Form eingelegt und der Hohlraum zwischen Ober- und Untergurt mit Schaum, insbesondere mit Polyurethan-Integralhartschaum ausgeschäumt wird (DE-OS 20 54 952).Various methods of making skis are known. One of these is the so-called injection process, in which the individual ski components, namely the upper chord, lower chord, edges, tip protectors, etc. are inserted into a closed mold and the cavity between the upper and lower chord is foamed with foam, in particular with integral rigid polyurethane foam (DE-OS 20 54 952).

Die auf diese Art und Weise hergestellten Skier haben den Nachteil, daß sich die Vorspannhöhe, welche den Anpreßdruck des Skis beim Fahren durch das Gewicht des Läufers regelt und die, um optimale Fahreigenschaften zu gewährleisten, insbesondere bei verschiedenen Temperaturen möglichst konstant bleiben soll, sich mit einer Änderung der Außentemperatur sehr stark ändert. Der Grund für diese starke Änderung der Vorspannhöhe mit einer Änderung der Temperatur liegt darin, daß die Verbindung zwischen glasfaserverstärktem Kunststoff (Laminat) und Thermoplastfolie, sei es am Untergurt, wo die Thermoplastfolie als Laufflächenbelag dient, oder am Obergurt, wo die Thermoplastfolie, z.B. eine ABS-Folie, als Oberflächenschutz dient, entweder direkt zwischen Folie und Laminierharz oder über duromere Klebstoffe, also in starrer Weise erfolgt. Dadurch wird jede thermische Bewegung der Thermoplastfolie oder des Kernmaterials mitgemacht und auf den Ski übertragen. Da aber das Laminat einen sehr geringen thermischen Ausdehnungskoeffizienten besitzt, Thermoplastfolie und Schaumkern jedoch einen wesentlich größeren, ändert sich bei einer Änderung der Außentemperatur die Vorspannung des Skis, und damit seine Fahreigenschaft sehr stark.The skis produced in this way have the disadvantage that the preload height, which regulates the contact pressure of the ski when skiing by the weight of the runner, and which, in order to ensure optimum skiing properties, should remain as constant as possible, especially at different temperatures, also changes a change in the outside temperature changes very much. The reason for this strong change in the preload height with a change in temperature is that the connection between glass fiber reinforced plastic (laminate) and thermoplastic film, be it on the lower flange, where the thermoplastic film serves as a tread surface, or on the upper flange, where the thermoplastic film, e.g. a ABS film, which serves as surface protection, either directly between the film and the laminating resin or via duromeric adhesives, i.e. in a rigid manner. As a result, every thermal movement of the thermoplastic film or the core material is included and transferred to the ski. However, since the laminate has a very low coefficient of thermal expansion, the thermoplastic film and foam core, however, have a much larger If the outside temperature changes, the pre-tension of the ski changes, and with it its skiing properties very strongly.

Bei Skiern, die nach einer anderen Bauweise, nämlich der sog. Sandwichbauweise, das heißt aus einem Formkörper, der aus einem Kern aus Holz, Schaumstoff oder dgl. und Seitenwangen aus ABS oder anderen Kunststoffen besteht, sowie dem darüber bzw. darunterliegenden, tragenden Obergurt bzw. Untergurt und den seitlich neben dem Untergurt angeordneten Stahlkanten sowie dem Laufflächenbelag aufgebaut sind, ist es bekannt, die einzelnen Teile, die in der richtigen Reihenfolge in eine Form gelegt und miteinander verklebt werden, nicht direkt zu verbinden, sondern eine Schicht aus einem elastomeren Werkstoff als Spannunsausgleich 'dazwischen zu legen. Diese Zwischenschicht wird überall dort angewendet, wo starre Teile, wie z.B. Kern und Obergurt bzw. Kern und Untergurt, miteinander zu verbinden sind. Aus der AT-PS 296 103 ist bekannt, daß diese elastomere Zwischenschicht gemeinsam sowohl die Stahlkanten als auch den tragenden Untergurt mit dem Formkörper des Skis verbinden kann. Die Verwendung elastischer oder plastischer Polymerer als schwingsdämpfende Zwischenschicht zwischen tragender Aluminiumlamelle und Stahlunter- bzw. -oberkante bzw. zwischen tragender Aluminiumlamelle und einer Phenolharzschichtstoffplatte als Seitenwange ist aus der AT-PS 351 416 bekannt. Hiebei wird das zur Bildung der Zwischenlage bestimmte Material in flüssigem Zustand auf die Oberfläche von zumindest einem der zu verklebenden Körper aufgetragen, gehärtet, mit Kleber versehen, und mit dem zweiten Körper verbunden, wodurch das beidseitige Auftragen von Kleber vermieden wird. In allen diesen bisher bekannten Fällen werden nur steife Körper, wie beispielsweise Skikern, Stahlkanten, Polyurethan-Hartschaum oder Laminat über eine elastomere Zwischenschicht miteinander verbunden, um beim Belasten eines Skis einen Spannungsausgleich zwischen den relativ starren Bauteilen zu bewirken.In the case of skis which have a different construction, namely the so-called sandwich construction, that is to say from a molded body which consists of a core made of wood, foam or the like and side walls made of ABS or other plastics, and the supporting upper chord above or below or lower chord and the steel edges arranged next to the lower chord as well as the tread covering, it is known not to directly connect the individual parts, which are placed in a mold in the correct order and glued to one another, but a layer made of an elastomer Place the material in between as tension compensation. This intermediate layer is used wherever rigid parts, e.g. Core and top flange or core and bottom flange are to be connected. From AT-PS 296 103 it is known that this elastomeric intermediate layer can jointly connect both the steel edges and the supporting lower flange to the molded body of the ski. The use of elastic or plastic polymers as a vibration-damping intermediate layer between the load-bearing aluminum lamella and the lower or upper edge of the steel or between the load-bearing aluminum lamella and a phenolic resin laminate plate as the side wall is known from AT-PS 351 416. Here, the material intended to form the intermediate layer is applied in the liquid state to the surface of at least one of the bodies to be bonded, hardened, provided with adhesive, and connected to the second body, thereby avoiding the application of adhesive on both sides. In all of these previously known cases, only rigid bodies, such as, for example, ski core, steel edges, rigid polyurethane foam or laminate, are connected to one another via an elastomeric intermediate layer in order to compensate for stress between the relatively rigid components when a ski is loaded.

Demgegenüber konnte nun gefunden werden, daß bei Skiern, die nach der . Injektionsbauweise hergestellt sind, bei Verwendung elastomerer Klebstoffe zwischen Laminat und thermoplastischer Folie, sei es am Untergurt oder auch , am Obergurt, die Vorspannung unabhängig von Temperaturänderungen besser erhalten bleibt, da der elastomere Klebestoff die thermischen Bewegungen von thermoplastischer Folie und Schaumstoffkern aufnehmen und wieder abgeben kann.In contrast, it has now been found that skis made after. Injection construction are produced, when using elastomeric adhesives between laminate and thermoplastic film, be it on the lower flange or also on the upper flange, the pre-tension is better maintained regardless of temperature changes, since the elastomeric adhesive prevents the thermal movements of can absorb thermoplastic film and foam core and release it again.

Gegenstand der vorliegenden Erfindung ist demnach ein Skibauteil aus thermoplastischen Folien und faserverstärkten, duromeren Kunststoffen (Laminaten) zur Verwendung im Verfahren zur Herstellung von Skiern nach dem Injektionsverfahren, dadurch gekennzeichnet, daß das als Untergurt dienende Laminat mit einem thermoplastischen Laufflächenbelag und/oder das als Obergurt dienende Laminat mit einem thermoplastischen Oberbelag durch einen elastomeren Kleber einer Schichtdicke von 0,05 bis 0,5 mm miteinander verbunden ist.The present invention accordingly relates to a ski component made of thermoplastic foils and fiber-reinforced, thermosetting plastics (laminates) for use in the method for producing skis by the injection method, characterized in that the laminate serving as the lower flange has a thermoplastic tread surface and / or as a top flange serving laminate with a thermoplastic covering is connected by an elastomeric adhesive with a layer thickness of 0.05 to 0.5 mm.

Als Klebstoffe eignen sich alle elastomeren Klebstoffe, das sind Kunststoffe mit einer Glasübergangstemperatur ) 0° C und einem Schubmodul im Bereich > 102 N/mm2 zwischen 20° C und der jeweiligen Zersetzungstemperatur. Besonders geeignet sind Polyurethane, vorzugsweise solche, die auf Basis hydroxylgruppenhaltiger Polyester aufgebaut sind, welche durch Isocyanate vernetzt werden. Die Klebstoffe können in lösungsmittelfreier Form oder gelöst in einem geeigneten organischen Lösungsmittel, wie z.B. Methylenchlorid oder Methyläthylketon verwendet werden. Besonders vorteilhaft ist die Auftragung in Lösung, wobei im Falle eines Polyurethanklebers darauf zu achten ist, daß Polyol und Isocyanat nicht vorzeitig miteinander reagieren. Die Auftragung kann sowohl einseitig auf das Laminat oder auf den Thermoplasten oder auch auf beide zu verklebenden Teile erfolgen, wobei der Kleber diskontinuierlich oder kontinuierlich, von Hand oder vorteilhafterweise über eine Rakel oder Gießmaschine aufgetragen wird. Die zu verklebenden Teile können vor der Verklebung in üblicher Weise vorbehandelt werden. So wird üblicherweise eine Polyäthylenfolie oxydativ vorbehandelt, ein GFK-Laminat meist angeschliffen, während ABS meist unvorbehandelt eingesetzt wird.All elastomeric adhesives are suitable as adhesives; these are plastics with a glass transition temperature) 0 ° C. and a shear modulus in the range> 10 2 N / mm 2 between 20 ° C. and the respective decomposition temperature. Polyurethanes are particularly suitable, preferably those based on hydroxyl-containing polyesters which are crosslinked by isocyanates. The adhesives can be used in solvent-free form or dissolved in a suitable organic solvent, such as methylene chloride or methyl ethyl ketone. Application in solution is particularly advantageous, but in the case of a polyurethane adhesive it must be ensured that polyol and isocyanate do not react prematurely with one another. The application can take place on one side on the laminate or on the thermoplastic or also on both parts to be bonded, the adhesive being applied discontinuously or continuously, by hand or advantageously using a doctor blade or casting machine. The parts to be glued can be pretreated in the usual way before gluing. For example, a polyethylene film is usually pre-treated oxidatively, a GRP laminate is mostly sanded, while ABS is mostly used untreated.

Die Verbindung erfolgt unter Hitze und Druck in Etagenpressen, kontinuierlichen Pressen, Kalandern oder anderen geeigneten Vorrichtungen. Wird ein Polyurethankleber eingesetzt, bildet sich durch diese Wärmeaktivierung aus dem Gemisch aus Polyol und Isocyanat der elastomere Zustand und damit der elastomere Klebstoff. Die Wahl der Schichtdicke des elastomeren Klebers innerhalb des erfindungsgemäßen Bereiches von 0,05 bis 0,5 mm hängt von der Rauhigkeit der zu verklebenden Flächen ab. Vorzugsweise beträgt die Schichtdicke des Klebers 0,1 bis 0,15 mm.The connection takes place under heat and pressure in multi-stage presses, continuous presses, calenders or other suitable devices. If a polyurethane adhesive is used, this heat activation creates the elastomeric state from the mixture of polyol and isocyanate and thus the elastomeric adhesive. The choice of the layer thickness of the elastomeric adhesive within the range of 0.05 to 0.5 mm according to the invention depends on the roughness of the surfaces to be bonded. The layer thickness of the adhesive is preferably 0.1 to 0.15 mm.

Das vorliegende Verfahren kann auch verwendet werden, wenn zwischen eine dicke, transparente Thermoplastfolie und das Laminat eine dünne, bedruckte Zwischenschicht eingebracht wird. Dies ist bisweilen vorteilhaft, wenn das schwierige Bedrucken dicker Platten z.B. aus HDPE dadurch vermieden werden soll, daß eine dünne, transparente, z.B. mit Hilfe von Rotationsdruck bedruckte Folie zwischen Laminat und dicke transparente Folie oder Platte gelegt wird. Die Verklebung aller drei Schichten erfolgt dann in einem Arbeitsgang, die dünne Zwischenschicht kann dabei auf beiden Seiten oder auch nur auf einer Seite von elastomerem Kleber umgeben sein.The present method can also be used if a thin, printed intermediate layer is introduced between a thick, transparent thermoplastic film and the laminate. This is sometimes advantageous if the difficult printing of thick plates e.g. HDPE should be avoided by using a thin, transparent, e.g. with the help of rotary printing, printed film is placed between the laminate and the thick transparent film or plate. All three layers are then bonded in one operation; the thin intermediate layer can be surrounded on both sides or only on one side by elastomeric adhesive.

Beispiel 1:Example 1:

Eine 1 mm dicke Folie aus HD-Polyäthylen, welches ein mittleres Molgewicht von ca. 100 000 besitzt, wurde mit einem unidirektionalen Laminat mit Hilfe eines Klebstoffes verklebt, der auf Basis eines linearen Polyesters aufgebaut ist, einen Hydroxylgehalt von ca. 1 % besitzt und mit 10 Gew.% Triphenylmethan-4,4',4"-trüsocyanat vernetzt ist. Der Klebstoff wurde dabei in einer Schichtdicke von jeweils 0,05 mm auf das HD-Polyäthylen und auf das Laminat aufgetragen, die zu verklebenden Teile wurden vereint und bei einem Druck von 6 bar, einer Temperatur von 100° C und einer Preßzeit von 10 sec verpreßt.A 1 mm thick film made of HD polyethylene, which has an average molecular weight of approx. 100,000, was glued to a unidirectional laminate with the help of an adhesive, which is based on a linear polyester, has a hydroxyl content of approx. 1% and is crosslinked with 10% by weight triphenylmethane-4,4 ', 4 "-truesocyanate. The adhesive was applied in a layer thickness of 0.05 mm each to the HD polyethylene and to the laminate, the parts to be bonded were combined and at a pressure of 6 bar, a temperature of 100 ° C and a pressing time of 10 sec.

Beispiel 2:Example 2:

Eine 0,6 mm dicke Folie aus ABS wurde mit einem unidirektionalen Laminat mit Hilfe eines Klebstoffes verklebt, der auf Basis eines linearen Polyesters aufgebaut ist, einen Hydroxylgehalt von ca. 1 % besitzt und mit 10 Gew.% Triphenylmethan-4,4',4"-triisocyanat vernetzt ist. Der Klebstoff wurde dabei in einer Schichtdicke von 0,15 mm auf das Laminat aufgetragen, die zu verklebenden Teile wurden vereint und bei einem Druck von 10 bar, einer Temperatur von 900 C und einer Preßzeit von 12 sec miteinander verpreßt.A 0.6 mm thick film made of ABS was glued to a unidirectional laminate with the aid of an adhesive which is based on a linear polyester, has a hydroxyl content of approx. 1% and contains 10% by weight triphenylmethane-4,4 ', crosslinked triisocyanate 4 ". the adhesive was thereby mm applied to the laminate in a layer thickness of 0.15, the parts to be bonded were combined and at a pressure of 10 bar, a temperature of 90 0 C and a pressing time of 12 sec pressed together.

Beispiel 3:Example 3:

Eine 1 mm dicke Folie aus HD-Polyäthylen, welches ein mittleres Molgewicht von 200 000 besitzt, wurde mit einem unidirektionalen Laminat mit Hilfe eines Klebstoffes verklebt, der auf Basis eines linearen Polyestes aufgebaut ist, einen Hydroxylgehlat von ca. 1 % besitzt und mit ca. 20 Gew.% eines Isocyanates vernetzt ist, welches durch Addition von 3 Molen 2,4-Toluylendiisocyanat mit 1 Mol Trimethylolpropan entsteht. Der Klebstoff wurde dabei in einer Schichtdicke von jeweils 0,04 mm auf das HD-Polyäthylen und auf das Laminat aufgetragen, die zu verklebenen Teile wurden vereint und bei einem Druck von 10 bar, einer Temperatur von 110° C und einer Preßzeit von 15 sec miteinander verpreßt.A 1 mm thick film made of HD polyethylene, which has an average molecular weight of 200,000, was glued to a unidirectional laminate with the help of an adhesive, which is based on a linear polyester, has a hydroxyl content of approx. 1% and approx 20% by weight of an isocyanate is crosslinked, which is formed by adding 3 moles of 2,4-tolylene diisocyanate with 1 mole of trimethylolpropane. The adhesive was applied in a layer thickness of 0.04 mm each to the HD polyethylene and the laminate, the parts to be glued were combined and at a pressure of 10 bar, a temperature of 110 ° C and a pressing time of 15 sec pressed together.

Beispiel 4:Example 4:

Aus den nach Beispiel 1, 2 und 3 hergestellten Skibauteilen wurde je 1 Langlaufski durch Verschäumen mit Polyurethan-Hartintegralschaum (Dichte 0,4 g/cm3) hergestellt. Die Vorspannhöhe der Skier betrug bei +150 C 20 mm. Bei Abkühlen auf -25° C stieg die Vorspannhöhe um 25 % auf 25 mm.1 cross-country ski was produced by foaming with rigid polyurethane integral foam (density 0.4 g / cm 3 ) from the ski components produced according to Examples 1, 2 and 3. The bias level of the skis was at +15 0 C for 20 mm. When cooling to -25 ° C, the leader height increased by 25% to 25 mm.

Weiters wurden 3 Skibauteile genau wie in Beispiel 1, 2 und 3 angegeben, hergestellt, jedoch erfolgte die Verklebung jeweils mit einem üblichen duromeren Klebstoff aus Epoxyharz. Aus den so gefertigten Skibauteilen, la, 2a und 3a, wurde ebenfalls ein Langlaufski durch Verschäumen mit Polyurethan-Hartintegralschaum (Dichte 0,4 g/cm3) hergestellt. Die Vorspannhöhe der Skier betrug bei +150 C 20 mm. Bei Abkühlen auf -25° C stieg die Vorspannhöhe um 50 % auf 30 mm.In addition, 3 ski components were manufactured exactly as specified in Examples 1, 2 and 3, but the bonding was in each case carried out using a conventional duromer adhesive made from epoxy resin. A cross-country ski was also made from the ski components thus manufactured, la, 2a and 3a, by foaming with rigid polyurethane integral foam (density 0.4 g / cm 3 ). The bias level of the skis was at +15 0 C for 20 mm. When cooling to -25 ° C, the pretension height increased by 50% to 30 mm.

Claims (5)

1. Skibauteil aus thermoplastischen Folien und faserverstärkten, duromeren Kunststoffen (Laminaten) zur Verwendung im Verfahren zur Herstellung von Skiern nach dem Injektionsverfahren, dadurch gekennzeichnet, daß das als Untergurt dienende Laminat mit einem thermoplastischen Laufflächenbelag und/oder das als Obergurt dienende Laminat mit einem thermoplastischen Oberbelag durch einen elastomeren Kleber einer Schichtdicke von 0,05 bis 0,5 mm miteinander verbunden ist.1. Ski component made of thermoplastic films and fiber-reinforced, thermosetting plastics (laminates) for use in the method for producing skis by the injection method, characterized in that the laminate serving as the lower flange with a thermoplastic tread surface and / or the laminate serving as the upper flange with a thermoplastic Upper covering is connected to one another by an elastomeric adhesive with a layer thickness of 0.05 to 0.5 mm. 2. Skibauteil nach Anspruch 1, dadurch gekennzeichnet, daß die Schichtdicke des elastomeren Klebers 0,05 bis 0,15 mm beträgt.2. Ski component according to claim 1, characterized in that the layer thickness of the elastomeric adhesive is 0.05 to 0.15 mm. 3. Skibauteil nach Anspruch 1, dadurch gekennzeichnet, daß der elastomere Kleber ein Polyurethan-Klebstoff ist.3. Ski component according to claim 1, characterized in that the elastomeric adhesive is a polyurethane adhesive. 4. Skibauteil nach Anspruch 3, dadurch gekennzeichnet, daß der Polyurethan-Klebstoff auf Basis hydroxylgruppenhaltiger Polyester, welche durch Isocyanate vernetzt werden, aufgebaut ist.4. Ski component according to claim 3, characterized in that the polyurethane adhesive is based on hydroxyl-containing polyester, which are crosslinked by isocyanates. 5. Skibauteil nach Anspruch 1, dadurch gekennzeichnet, daß zwischen Folie und Laminat eine dünne, bedruckte Zwischenschicht eingebracht wird, die über einen elastomeren Kleber mit Folie und Laminat verbunden ist.5. Ski component according to claim 1, characterized in that a thin, printed intermediate layer is introduced between the film and laminate, which is connected to the film and laminate via an elastomeric adhesive.
EP80106440A 1979-12-27 1980-10-22 Ski construction element Withdrawn EP0031412A1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE2952415 1979-12-27
DE2952415 1979-12-27

Publications (1)

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EP0031412A1 true EP0031412A1 (en) 1981-07-08

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EP80106440A Withdrawn EP0031412A1 (en) 1979-12-27 1980-10-22 Ski construction element

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EP (1) EP0031412A1 (en)
JP (1) JPS56100075A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2611346A1 (en) * 1987-02-26 1988-09-02 Isovolta PROCESS FOR THE MANUFACTURE OF SKIS
EP0366979A3 (en) * 1988-11-01 1991-11-13 Cytec Technology Corp. Improved interleaf layer in fiber reinforced resin laminate composites

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE19621547A1 (en) 1996-05-29 1997-12-04 Schaerer Soehne Ag Usm U Modular interior system

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1428863A1 (en) * 1962-09-10 1969-04-03 Brown Jr Culver S Elastic layered ski
DE1923367A1 (en) * 1969-05-07 1970-11-19 Max Waxenberger Composite ski with rubber core for set prop- - erties
DE2054952A1 (en) * 1969-11-07 1971-05-19 Nippon Gakki Seizo K K , Hamamatsu, Shizuoka (Japan) Layered ski and method of making it
DE2033845A1 (en) * 1970-07-01 1972-01-20
DE2461461A1 (en) * 1974-12-24 1976-07-08 Schloemann Siemag Ag PLASTIC SKI
DE2506289A1 (en) * 1975-02-14 1976-08-26 Sarner Tyrol Gmbh & Co Kg Ski with patterned surface coating and transparent covering layer - manufactured without polishing to eliminate dust suppression requirements
AT351416B (en) * 1977-12-09 1979-07-25 Isovolta METHOD OF BONDING TWO BODIES TOGETHER

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1428863A1 (en) * 1962-09-10 1969-04-03 Brown Jr Culver S Elastic layered ski
DE1923367A1 (en) * 1969-05-07 1970-11-19 Max Waxenberger Composite ski with rubber core for set prop- - erties
DE2054952A1 (en) * 1969-11-07 1971-05-19 Nippon Gakki Seizo K K , Hamamatsu, Shizuoka (Japan) Layered ski and method of making it
DE2033845A1 (en) * 1970-07-01 1972-01-20
DE2461461A1 (en) * 1974-12-24 1976-07-08 Schloemann Siemag Ag PLASTIC SKI
DE2506289A1 (en) * 1975-02-14 1976-08-26 Sarner Tyrol Gmbh & Co Kg Ski with patterned surface coating and transparent covering layer - manufactured without polishing to eliminate dust suppression requirements
AT351416B (en) * 1977-12-09 1979-07-25 Isovolta METHOD OF BONDING TWO BODIES TOGETHER

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2611346A1 (en) * 1987-02-26 1988-09-02 Isovolta PROCESS FOR THE MANUFACTURE OF SKIS
EP0366979A3 (en) * 1988-11-01 1991-11-13 Cytec Technology Corp. Improved interleaf layer in fiber reinforced resin laminate composites

Also Published As

Publication number Publication date
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