• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a process for the production of composites using textile fabrics, the structure of which exhibit aperiodic differences in weave density, and which serve in conjunction with reinforcement materials to make them more resistant to cracking and more robust against stress loads and imperfections in the material. In the manufacture of aperiodic woven fabrics, the invention relates to the use of weaving machines controlled by computer using the recursive inductive rotation (IR) method - Patent Application A1515 / 2011. In particular, by the composite with several layers of different aperiodically woven - and thus weiterere tear-resistant - textiles it comes in all directions to higher crack resistance. As a result of aperiodically occurring denser and looser reinforcements, there are planned aperiodically occurring predetermined breaking points, so that at the same time any load energy is not locally effective, but derived along these points in the material - delocalized - is. Such delocalisation of the damage of defects in the material justifies the fault tolerance in the composite material. This process is excellently suited for the manufacture of fiber composites where, for example, carbon fiber, glass fiber, synthetic fiber, natural fiber are bonded into the plastic or concrete bedding matrix.
    公开号:AT515438A1
    申请号:T115/2014
    申请日:2014-02-18
    公开日:2015-09-15
    发明作者:
    申请人:Hofstetter Kurt;
    IPC主号:
    专利说明:

    Bescnreimmg
    The invention relates to a process for the production of composite materials using textile fabrics (such as carbon fibers, for example).
    Glass fibers, plastic fibers, natural fibers, etc.) whose structure has aperiodic differences in weave density and which are used in conjunction with materials (such as plastic, concrete, etc.) for reinforcement (see Fig. 1). The permanent oscillation of loose and dense reinforcement or reinforcement in aperiodic order causes an irregularity or inhomogeneity in the composite material.
    The aim of the invention is to propose a method as indicated above, to make the textile composite materials more resistant to cracking or tear propagation and overall more robust against incorrect loads and defects in the material. In particular, by the composite with several layers of different aperiodically woven and thus tear-resistant textiles (test result according to ISO standards table see below) it comes to the three-dimensional inhomogeneity of the material structure and higher crack resistance. As a result of the aperiodically occurring loose reinforcements or reinforcements - and thus planned aperiodically occurring predetermined breaking points - the load energy is not locally effective, but derived along these points in the material - delocalized. The composite material thus becomes more robust against false loads, since each directional loading force loses and weakens due to the aperiodically occurring predetermined breaking points in constantly changing directions. Thus it comes to the delocalization of the damage of defects in the material and thus the fault tolerance.
    The description of the invention is illustrated by exemplary schematic drawings Figs. 1-4.
    The invention relates to all processes for the production of textile composite materials, the one or more layers in the bedding matrix of the respective material aperiodically woven textiles (see Fig. 1, Fig. 3 and Fig. 4) and thus no single or multi-ply periodically woven textiles (such as woven in plain weave textiles - see Fig. 2) can bring together. In addition, the combined superposition of periodic and aperiodic fabrics can be used in the manufacture of composites to improve the materials previously associated with periodic woven textiles without losing their previous basic structures. These processes are excellently suited for the production of fiber composite materials, but also for composite laminates, in which case the components of a composite material can themselves be composites.
    In the production of aperiodic-weave fabrics, the present invention relates to the recursive inductive rotation (IR) methods of patent application A1515 / 2011, in which the three-step IR method is of particular importance for such fabric fabrication. In this case, a fabric is produced by means of a computer-controlled weaving machine, wherein a fabric pattern having a square basic figure, which corresponds to a crossing point of threads, is arranged several times in the fabric (see FIGS. 1 and 3).
    The computer control is carried out such that at a square output figure Q, which is composed of a plurality of square basic figures, that is, a plurality of crossing points of threads, in one side center, an edge-side rotation point is set, then three copies of this output figure successively by 90 ° , 180 ° and 270 ° rotated and positioned in a fan-like manner in order to obtain a composite figure, which then as
    Initial figure for a corresponding subsequent fan-like composition of their successively rotated copies by 90 °, 180 ° and 270 ° is set, so iteratively develop arbitrarily large figures from crossing points of threads corresponding to the tissue, wherein the threads in the tissue aperiodic and asymmetric above and cross below. The basic figures are not invariant upon rotation. Due to a precise overlap of the figures, the three-step IR method simultaneously creates a second, parallel, hidden, aperiodic and asymmetric tissue pattern, the so-called background tissue pattern, which lies exactly behind and different from the tissue pattern visible in the foreground. The background tissue can additionally be brought together as a second superimposed tissue and significantly strengthen the composite in three dimensions.
    This basic procedure in the three-step IR method is further illustrated by way of example with reference to the drawings Fig. 5 - Fig. 7, wherein by way of example the output figures of each iteration are rotated clockwise and the central eastern, i. rightmost point of the starting characters is set as a rotation point.
    In Fig. 5, Fig. 5a shows a square output figure Q for a three-step IR method, which is composed of a plurality of square basic figures, that is, a plurality of crossing points of threads; in FIG. 5b, the different stages of the first iteration R (l), starting from the output figure Q according to FIG. 5a; Fig. 5c shows the first three iterations of the recursion R = Q, R (l), R (2) and R (3) side by side and illustrates the repeated recursive application of the three step IR method of Fig. 5b to achieve more complex structures;
    Fig. 6 is a view similar to Fig. 5c, wherein the output figure Q for the three-step IR method is divided into parts indicated by different arrows, so as to obtain the achievable pattern - also with respect to the asymmetry and aperiodicity in the present Web process - better to illustrate;
    Fig. 7 is a view similar to Fig. 5c, illustrating the preparation of the aperiodic tissue as shown in Fig. 3; where the output figure Q for fabric fabrication is formed according to the three-step IR method from a set of four Web nodes corresponding to four Web thread crossing points. The result is a network of lines (dark lines = threads) that cross each other aperiodically below or above.
    Aperiodic differences in web density lead to corresponding aperiodic textile concentrations.
    The State Research Institute for Textiles and Informatics carried out the testing of a non-periodically woven textile according to the EN ISO standards using a computer-controlled jacquard weaving machine according to the three-step IR method (see the following test report - table). In the table, this aperiodic woven fabric having the weave structure as shown in Fig. 1 is referred to as " IR prototype " designated. Exemplary use of "Tencel". Viscose staple fibers were found to have significantly higher tear strength in both the warp and weft directions compared to periodic fabrics such as crepe and twill weaves of the same warp and weft density. Moreover, due to the aperiodically occurring loose weave densities, this test, as would be expected, exhibited a blatantly higher air permeability. The maximum tensile force in the warp direction remained the same and even slightly increased in the weft direction.
    Source: State Research Institute for Textile and Computer Science,
    Vienna 9.1.2014, reviewed by DI Christian Spanner
    In the composite material, therefore, a higher crack resistance and at the same time a higher fault tolerance is to be expected, above all as a result of the aperiodically woven predetermined breaking points - delocalization of the loading force or distribution of the damage to the material as a whole.
    To the state of the art
    The production of textile composites according to the present invention relates in particular to the field for the production of fiber composites:
    A fiber composite material generally consists of two major components: a bedding matrix and reinforcing fibers. By mutual interactions of the two components of this material receives higher quality properties than each of the two individually involved components.
    Unlike composite materials, such as reinforced concrete, the introduction of extremely thin fibers makes use of, among other things, the effect of specific strength. To the
    To influence strength in different directions, instead of individual fibers, fabrics or scrims are used which are produced before contact with the matrix.
    In addition to fabrics of carbon, ceramic, aramid, boron, basalt, steel, natural and nylon fibers, it is mainly glass fiber textiles that are used in conjunction with plastic, but also concrete, metal, ceramic and carbon. The fiber-plastic composites include, in particular, carbon fiber reinforced plastic (CFRP), glass fiber reinforced plastic (GRP), aramid fiber reinforced plastic (AFK), natural fiber reinforced plastic (NFP) and wood plastic composites (WPC).
    In the production of composites with textile fabrics in addition to the material properties of the components in general, their geometry is also essential (size, shape, etc.). The geometric relationships with regard to their periodic and aperiodic structural order have so far been disregarded in particular in the network theory, a design method for fiber-plastic composites.
    In order to illustrate the invention in more detail, the method according to the invention is explained below by way of example in the specific production method of 1) carbon fiber reinforced plastic (CFRP) and 2) textile-reinforced concrete (textile concrete). 1) carbon fiber reinforced plastic (CFRP) refers to a fiber-plastic composite material in which carbon fibers, usually in multiple layers, are embedded as reinforcement in a plastic matrix.
    The matrix usually consists of duromers, for example epoxy resin, thermoplastics or biopolymers. For thermally highly stressed components, the carbon fiber can also be bound in a ceramic matrix.
    The strength of a material made of CFRP, as with all fiber-matrix composites, is much higher in the fiber direction than transverse to the fiber direction. The strength is lower across the fiber than with an unreinforced matrix. Therefore, individual fiber layers are laid in different directions. In order to influence the strength in various directions, woven fiber fabrics in periodical plain weave (see FIG. 2) are used which are produced before contact with the matrix and also superimposed (see FIG. 2 a). In the present invention, aperiodically woven fiber textiles (see FIGS. 1 and 3) are used by computer controlled textile machines according to the three-step IR method. By multiple superimposition of such textile fabrics (see Fig. 4: Fig. 3 superimposed Fig. 1) occurs in the composite three-dimensional in all directions for aperiodic fiber reinforcement or material reinforcement. By this aperiodic reinforcement a higher crack resistance of the composite material is achieved and especially by the delocalisation of the damage is given a greater tolerance to faulty loads. This just helps to produce high performance engineering components and would save the most costly treatments and coatings of the fibers to achieve this strength. 2) Textile concrete uses technical textiles, usually scrim. As fiber material textiles from Hochleistungsendlosfasern such. B. alkali-resistant glass or carbon, which have the great advantage of not rusting. The present invention relates to the use of textile fabrics of yarns of these fiber materials, which in turn consist of many continuous filaments and by means of computer-controlled textile machines after the three
    Process step IR method into grid-like aperiodic weave structures. The overlaying of two or more such aperiodic textiles in combination with high-strength fine concrete in a sandwich method results in three-dimensional · inhomogeneous, crack-resistant textile concrete, which, due to the delocalization of the damage, is significantly more robust against faulty loads and imperfections in the fine concrete.
    Since in the three-step IR method different starting figures (= prototypes) result in different aperiodicities (see, for example, FIG. 1 versus FIG. 3) of the textile bond, then the production method and geometry of the textiles can be varied and tailor-made according to the starting figure used be provided for a variety of applications.
    权利要求:
    Claims (2)
    [1]
    1. A process for the production of textile composite materials, characterized in that in the bedding matrix of the respective material or multilayer composite technical textiles have aperiodic tissue structures and by means of computer-controlled weaving machines by the method of inductive rotation (IR) (Patent Application A 1515/2011), in particular to increase the crack resistance and fault tolerance against stress loads of the composite material.
    [2]
    2. Method as in claim 1, characterized in that in the bedding matrix of the respective material multilayer composite technical textiles have a combination of periodic and aperiodic tissue structures.
    类似技术:
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    同族专利:
    公开号 | 公开日
    AT515438B1|2015-12-15|
    WO2015123711A1|2015-08-27|
    DE112015000840A5|2016-11-24|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US5855991A|1996-11-05|1999-01-05|Milliken Research Corporation|Composite textile structure|
    JP2005344256A|2004-06-04|2005-12-15|Nisshinbo Ind Inc|High-strength composite woven fabric and method for producing the same|
    WO2010126598A1|2009-04-29|2010-11-04|Gore Enterprise Holdings, Inc.|Burn protective materials|WO2016154649A1|2015-03-30|2016-10-06|Kurt Hofstetter|Aperiodically woven textile|FR2671111B1|1990-12-28|1993-03-19|Chaignaud Silac Ets L A|MULTICHAIN TEXTILE STRUCTURE WOVEN IN THREE DIMENSIONS AND MANUFACTURING METHOD THEREOF.|
    US7712488B2|2008-03-31|2010-05-11|Albany Engineered Composites, Inc.|Fiber architecture for Pi-preforms|
    AT512060B1|2011-10-17|2015-02-15|Hofstetter Kurt|METHOD FOR PRODUCING A PATTERN STRUCTURE|
    法律状态:
    2021-12-15| HA| Change or addition of new inventor|Inventor name: KURT HOFSTETTER, AT Effective date: 20211021 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA115/2014A|AT515438B1|2014-02-18|2014-02-18|Process for the production of textile composite materials with higher crack resistance and fault tolerance|ATA115/2014A| AT515438B1|2014-02-18|2014-02-18|Process for the production of textile composite materials with higher crack resistance and fault tolerance|
    DE112015000840.3T| DE112015000840A5|2014-02-18|2015-02-18|Textile composite material and process for its production|
    PCT/AT2015/050045| WO2015123711A1|2014-02-18|2015-02-18|Textile composite material and method for producing same|
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