DE102009005587A1 - Method for determining reference force of e.g. spunbonded fabric, utilized as carrier insert for producing roofing sheet, involves comparing reinforced planar structure exhibiting reference force with planar structure without reinforcement - Google Patents

Abstract

The method involves removing a sample of a reinforced planar structure by punching holes in the reinforced planar structure for measurement of reference force. Reinforcement of the reinforced planar structure is transectioned in accordance with the removal of the sample. The reference force at the punched sample is measured at low extensions in the range of 0 to 5 percentage at 20 degree Celsius. Force-extension diagram is determined. The reinforced planar structure with the measured reference force is compared with a planar structure without reinforcement.

Description

The The invention relates to a method for quality assurance of reinforced, flat structures, in particular of reinforced, textile fabrics or reinforced films.

Toughened planar structures are considered technical products in many Applications, eg. B. as a carrier insert used.

Reinforcing inserts, For example, for the production of roofing membranes, must be diverse Requirements met. In particular, carrier inserts must sufficient mechanical stability, such as good perforation resistance and good tensile strength, which, for example, in further processing, such as bituminization or misplacing occur. In addition, will a high resistance to thermal stress, for example when bituminizing or against radiant heat, and resistance required against flying fire.

Reinforced carrier inserts based on synthetic fiber nonwovens and reinforcing fibers or reinforcing threads, for example based on glass fibers, can be found in US Pat GB-A-1,517,595 . German Utility Model-77-39.489 . EP-A-160.609 . EP-A-176-847 . EP-A-403,403 and EP-A-530.769 , Such products show improved mechanical stability compared to the unreinforced nonwoven fabric.

The Connection between fiber fleece and reinforcing fibers takes place according to this prior art either by gluing by means of a Binders or by needling the layers of different Material.

It is also known to produce composites by knitting or sewing techniques. Examples of this can be found in DE-A-3,347,280 . US-A-4,472,086 . EP-A-333.602 and EP-A-395.548 ,

Out DE-A-3,417,517 is a textile interlining with anisotropic properties and a method for its preparation known. The interlining material consists of a substrate which has a surface which melts below 150 ° C. and associated reinforcing filaments which melt over 180 ° C. and are fixed parallel to one another on this surface. According to one embodiment, the substrate can be a nonwoven fabric, on the one surface of which melt adhesive fibers or threads are provided, which are provided for producing an adhesion of the parallel arranged reinforcing fibers with the nonwoven fabric.

Out US-A-4,504,539 is a combination of reinforcing fibers in the form of bicomponent fibers with nonwoven fabrics based on synthetic fibers known.

From the EP-A-0,281,643 is a combination of reinforcing fibers in the form of a network of bicomponent fibers with nonwovens based on synthetic fibers known, wherein the weight fraction of the network of bicomponent fibers is at least 15 wt .-%.

From the JP-A-81-5879 For example, a composite is known which is provided with a reticulated reinforcing material.

From the GB-A-2,017,180 is a filter material made of inorganic nonwoven material and metal wires known, which is used for exhaust air purification at high temperatures (higher than 300 ° C).

DE-Gbm-295 00 830 describes the reinforcement of a glass fleece with synthetic monofilaments.

DE-A-3,941,189 discloses a combination of reinforcing fibers in the form of a thread chain with nonwovens on the basis of synthetic fibers known, which can be interconnected in a variety of ways.

Out EP-A-0,806,509 and EP-A-0,806,510 are carrier inserts, containing a fabric and a reinforcement, known that absorb the acting force even at a low elongation. Such carrier inserts show good performance properties. In the production of such reinforced structures, the reinforcement is supplied under tension so that it is installed oriented. For quality assurance, products must always be inspected and compliance with product specifications ensured. However, such studies are not trivial.

It Therefore, the task was a method for the investigation of amplified, planar structures, in particular of reinforced, textile fabrics or reinforced films, provide, by means of the low strains, in particular at strains from 0 to 5%, it can be investigated whether the installation the gain a derivative of acting tensile forces guaranteed.

• a) Entnehmen von mindestens einer Probe des verstärkten flächigen Gebildes zur Messung der Bezugskraft,
• b) Entnehmen von mindestens einer Probe des verstärkten flächigen Gebildes zur Messung der Bezugskraft,
• c) Durchtrennung der Verstärkung in der gemäß Schritt a) entnommenen Probe durch Ausstanzen von Löchern,
• d) Ausstanzen von Löchern in der gemäß Schritt b) entnommenen Probe, wobei die Fläche der ausgestanzten Löcher in Schritt c) und die Fläche der ausgestanzten Löcher in Schritt d) gleich oder annährend gleich ist, die Anzahl der ausgestanzten Löcher in Schritt c) und die Anzahl der ausgestanzten Löcher in Schritt d) gleich ist, und die Verstärkungen vollständig erhalten bleiben,
• e) Messung der Bezugskraft an den mit Ausstanzungen versehenen Proben aus Schritt c) und d) im geringer Dehnungen, vorzugsweise im Bereich 0 bis 5% Dehnung, und Bestimmung des Kraft-Dehnungs-Diagramm (Messung bei 20°C),
• f) Vergleich der in Schritt e) gemessenen Bezugskräfte.

The subject matter of the present invention is a method for determining the reference force of the reinforced planar structure compared with the planar structure without reinforcement in the region of low elongations, preferably between 0 and 5% elongation, at at least one location and the change thereof comprising the steps:

• a) taking at least one sample of the reinforced sheet for measuring the reference force,
• b) taking at least one sample of the reinforced sheet for measuring the reference force,
• c) separation of the reinforcement in the sample taken in step a) by punching out holes,
• d) punching out holes in the sample taken in step b), wherein the area of the punched holes in step c) and the area of the punched holes in step d) are equal or approximately equal, the number of punched holes in step c) and the number of punched holes in step d) is the same, and the reinforcements are completely preserved,
• e) Measurement of the reference force on the punched samples from steps c) and d) at low strains, preferably in the range 0 to 5% elongation, and determination of the force-strain diagram (measurement at 20 ° C),
• f) Comparison of the reference forces measured in step e).

The inventive method allows a determination of the change in the reference forces, which caused by the incorporation of a reinforcement. Furthermore, the method allows to check whether the installation of the reinforcement is an immediate drainage of acting forces on reinforcement.

at the examined reinforced planar structures it is preferably reinforced reinforcements, which have a gain and in the force-strain diagram (at 20 ° C) show that the reference force of the area Structure with reinforcement compared to the surface Structures without reinforcement in the range between 0 and 5% elongation, preferably between 0 and 3%, in particular between 0 and 1%, at least 10%, preferably at least 20%, in particular preferably by at least 30%, different.

Of the in accordance with step e) the preload force, expressed in Centinewton and corresponds to the numerical value the basis weight of the sample, expressed in grams per square meter.

REINFORCEMENT OF THE FLAT structure

The to be examined planar structure has at least one Reinforcement on.

The Reinforcement is designed such that the gain absorbs a force, so that in the force-strain diagram (at 20 ° C) the reference force of the flat structure with Reinforcement compared to the flat structure without reinforcement in the region of low elongations, preferably between 0 and 3%, in particular between 0 and 1%, at least 10%, preferably at least 20%, especially preferably at least 30%, different.

at the reinforcements are preferably reinforcing threads and / or yarns whose Young's modulus is at least 5 Gpa, preferably at least 10 Gpa, more preferably at least 20 Gpa. The aforementioned reinforcing threads, d. H. both the monofilaments and the yarns have a diameter between 0.1 and 1 mm or 10-400 tex, preferably 0.1 and 0.5 mm, in particular 0.1 and 0.3 mm and have an elongation at break from 0.5 to 100%, preferably 1 to 60%. Especially advantageous they have a stretch reserve of less than 2%, in particular less than 1%, up.

When Stretching reserve is termed the elongation that refers to the reinforced planar structures act before the acting force the gain is derived, d. H. a stretch reserve 0% would mean that the acting tensile forces would be derived immediately to the reinforcement. This means that the acting forces are not just an alignment or orientation of the gain cause but rather be derived directly on the reinforcement, so that one Damage to the planar structure can be avoided can. This is particularly evident in a steep rise in the force to be applied at small strains (force-strain diagram at room temperature).

Prefers be as reinforcements threads, especially multifilaments and / or monofilaments, based on polyester, aramids, preferably so-called High modulus aramids, carbon, glass, glass rovings, mineral fibers (Basalt), high-strength polyester monofilaments or multifilaments, high-strength polyamide monofilaments or multifilaments, and so-called Hybrid multifilament yarns (yarns containing reinforcing fibers and lower melting binding fibers) or wires (monofilaments) made of metals or metallic alloys.

preferred Reinforcements exist for economic reasons of glass multifilaments in the form of - essentially - parallel Threads of yarn or torn. Mostly only one reinforcement in Longitudinal direction of the planar structure by - substantially - parallel running yarn bundles.

The Reinforcing threads can be as such or also in the form of its own textile fabric, for example used as a fabric, scrim, knit, knitted fabric or fleece become. Preferably, reinforcements are parallel to each other current reinforcing yarns, so Kettfadenscharen, as well Scrim or tissue.

The Thread density may vary depending on the desired Property profile vary within wide limits. Preferred is the thread density between 20 and 250 threads per meter. The Yarn density is measured perpendicular to the thread running direction. The reinforcing threads are preferably during the formation of the planar Structure, preferably in spunbonding, supplied and embedded. Also preferred is a subsequent Reinforcement of the planar structure possible, z. By assembling.

The measurement of the reference force takes place after EN 29073 , Part 3, on 5 cm wide samples with a 200 mm clamping length. The measurement is carried out at room temperature (20 ° C). The numerical value of the prestressing force, expressed in centinewtons, corresponds to the numerical value of the basis weight of the sample, expressed in grams per square meter.

EXPERIENCED WORKS

Of the Term "planar structure" is in the context of this To understand description in its broadest meaning. Preferably these are textile fabrics and / or Films. Textile fabrics may be all Structures made of fibers act according to a surface-forming technique have been produced. When the fiber-forming materials act it is natural fibers and / or fibers of synthesized polymers. Examples of such fabrics are Fabrics, scrims, knits and knits, and preferably nonwovens.

From nonwovens made of synthetic polymers fibers are spunbonded nonwovens, so-called spunbonds, which are melt-spun by a wirral layer Filaments are produced, preferably. They consist of endless synthetic fibers melt-spinnable polymer materials. Suitable polymer materials For example, polyamides, such as. B. polyhexamethylene diadipamide, Polycaprolactam, aromatic or partially aromatic polyamides ("aramids"), aliphatic polyamides, such as. As nylon, partially aromatic or wholly aromatic Polyester, polyphenylene sulfide (PPS), polymers with ether and keto groups, such as As polyether ketones (PEK) and polyetheretherketone (PEEK), Polyolefins, such as. As polyethylene or polypropylene, or polybenzimidazoles. In addition to the spunbonded nonwovens can also Stapelfaservliese be used.

Prefers the spunbonded nonwovens consist of melt-spinnable polyesters. Especially advantageous are spunbonded nonwovens, which comprise at least 85 mol% of polyethylene terephthalate consist. The remaining 15 mol% then build up from dicarboxylic acid units and glycol units, which are known as modifiers act and which allow the skilled person, the physical and targeted chemical properties of the filaments produced influence.

Especially preferred are polyesters containing at least 95 mol% of polyethylene terephthalate (PET), especially those from unmodified PET.

The in the spunbonded polyester preferably have a Molecular weight corresponding to an intrinsic viscosity (IV), measured in a solution of 1 g of polymer in 100 ml Dichloroacetic acid at 25 ° C, from 0.6 to 1.4.

The Single titer of polyester filaments in spunbonded between 1 and 16 dtex, preferably 2 to 8 dtex.

The textile surface or the spunbonded nonwoven fabric should also be a meltbond-bonded nonwoven fabric which contains carrier and hot-melt adhesive fibers. Such meltbond-solidified spunbonded nonwovens are, for example, in EP-A-0,446,822 and EP-A-0,590,629 described.

The Textile fabrics usually become one subjected to mechanical and / or chemical solidification.

Insofar as the consolidation takes place mechanically by needling, it is carried out with stitch densities of 20 to 100 stitches / cm ² , preferably 40 stitches / cm ² , the needling being done by means of needles whose notch protrusion, preferably the sum of notch protrusion and notch depth, is smaller is considered the diameter of the reinforcement, damage to the reinforcing threads is avoided.

Of Furthermore, the solidification can also be hydrodynamic, in particular by water jet needling. In place of water can also other liquid media are used.

Contain the textile fabrics are not for thermal consolidation capable binding fibers or only slightly for thermal consolidation competent binder fiber, so they are with a binder, preferably one or more chemical binders, impregnated or additionally impregnated. In particular come to this chemical binders based on acrylates or styrenes in question. In addition to chemical binders, binders based on Strengths are used. The binder content is conveniently up to 30 wt .-%, preferably 2 to 25 wt .-%. The exact choice of the binder is made according to the specific Interests of the processor.

The the nonwovens constituting filaments or staple fibers can have a virtually round cross section or other shapes such as dumbbell, kidney-shaped, triangular or tri- or multilobal cross sections. They are also hollow fibers and bi or Multi-component fibers can be used. Furthermore, the Use melt adhesive fiber also in the form of bi- or multi-component fibers.

The flat structures, in particular the textile fabric, can be constructed in one or more layers, and this also for Slides applies.

The basis weight of the textile fabric, in particular of the spunbonded fabric, is between 20 and 500 g / m ² , preferably 40 and 400 g / m ² , in particular 120 and 300 g / m ² . The weight per unit area referred to above - insofar as binders are used - refers to structures with binder.

The flat structures may also be a film, preferably a film of synthetic polymers, in particular of fusible Polymers.

HOLES

The Punching out the holes in step c) and d) takes place by means of known punching machines, being sure that all Reinforcements in the sample to be examined in step c) are severed.

The Form of punching is freely selectable, with round and / or square cutouts are the most practical.

The Area of holes resulting from the punched holes in both samples is equal or approximately equal. Preferably the two areas do not differ more than 10%, preferably not more than 5%.

The Diameter or largest diagonal of the punched holes are in both samples equal or approximately the same. Preferably different the two diameters or diagonals are not more than 10%, preferably by not more than 5%.

Essential is that the number of punched holes in step c) and the number of punched holes in step d) is the same so that comparability is ensured.

The Stamping patterns in steps c) and d) should be comparable, i. H. have comparable distances, so that at the punching in step d) no additional weakening of the planar structure is generated, but only through the severing / punching in step c) produced weakening compensated for the planar structure, d. H. balanced, so that comparability is ensured

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - GB 1517595 A [0004]
• - DE 77-39489 U [0004]
• - EP 160609 A [0004]
• - EP 176-847 A [0004]
• - EP 403403 A [0004]
• - EP 530769 A [0004]
• - DE 3347280 A [0006]
• - US 4472086 A [0006]
• - EP 333602 A [0006]
• - EP 395548 A [0006]
• - DE 3417517 A [0007]
• - US 4504539 A [0008]
• - EP 0281643 A [0009]
• - JP 81-5879 A [0010]
• - GB 2017180 A [0011]
• DE 29500830 U [0012]
• - DE 3941189 A [0013]
• - EP 0806509 A [0014]
• EP 0806510 A [0014]
• EP 0446822A [0035]
• - EP 0590629 A [0035]

Cited non-patent literature

• - EN 29073 [0028]

Claims (16)

Method for determining the reference force of the reinforced planar structure compared with the flat structures without reinforcement in the area lower Strains, preferably between 0 and 5% elongation, at least a job and its modification comprising the steps: a) Take at least one sample of the reinforced sheet Structure for measuring the reference force, b) Take at least a sample of the reinforced planar structure for measuring the reference force, c) separation of amplification in the sample taken in step a) Punching holes, d) punching out holes in the sample taken in step b), wherein the area of the punched holes in step c) and the area of the punched holes in Step d) is equal or approximately equal, the number the punched holes in step c) and the number of punched holes in step d) is the same, and the Reinforcements completely preserved, e) Measurement of the reference force on the punched samples from step c) and d) at low elongations, preferably in the range 0 to 5% elongation, and determination of the force-strain diagram (measurement at 20 ° C), f) comparison of the measured in step e) Reference forces. Process according to claim 1, characterized characterized in that to be examined reinforced area Structure is a reinforced liner insert. Process according to claim 1, characterized characterized in that to be examined reinforced area Structure in force-strain diagram (at 20 ° C) higher Reference force compared to the flat structure without reinforcement preferably at least 10%. A method according to claim 3, characterized characterized in that the measurement of the respective reference force in the range between 0 and 3% elongation, preferably between 0 and 1%. Process according to claim 1, characterized characterized in that the reinforcements are reinforcing threads and / or yarns whose Young's modulus is at least 5 Gpa, preferably at least 10 Gpa, more preferably at least 20 Gpa. A method according to claim 5, characterized characterized in that the reinforcements have a breaking elongation from 0.5 to 100%, preferably 1 to 60%. A method according to claim 5, characterized characterized in that the reinforcements a strain reserve less than 2%, in particular less than 1%. Process according to claim 1, characterized characterized in that it is in the flat structure is a textile fabric and / or a film. A method according to claim 8, characterized characterized in that it is the textile fabric is a structure of fibers, preferably comprising fibers Natural fibers and / or fibers of synthesized polymers. A method according to claim 9, characterized characterized in that it is the textile fabric to a fleece, fabric, scrim, knitted fabric and knitted fabrics, and preferably is a spunbond and / or Stapelfaservlies. A method according to claim 10, characterized characterized in that the nonwoven is a spunbonded nonwoven Fibers made of synthetic polymers. A method according to claim 8, characterized characterized in that it is in the flat structure to a film of synthetic polymers, in particular of fusible Polymers, acts. Process according to claim 1, characterized characterized in that in step c) severed all reinforcements become. Process according to claim 1, characterized characterized in that the area of the through the cutouts resulting holes in both samples is the same. Process according to claim 1, characterized characterized in that the area of the through the cutouts resulting holes in both samples are no more than 10%, preferably not more than 5%. Process according to claim 1, characterized characterized in that the punching patterns in step c) and d) are comparable are, so that at the punching in step d) no additional Weakening of the planar structure is generated special only through the cutting / punching in step c) compensated for weakening of the planar structure, d. H. balanced, will.