WO2024098157A1 - Matériau de remplissage à base de rafle de maïs pour pelouses synthétiques - Google Patents

Matériau de remplissage à base de rafle de maïs pour pelouses synthétiques Download PDF

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Publication number
WO2024098157A1
WO2024098157A1 PCT/CA2023/051502 CA2023051502W WO2024098157A1 WO 2024098157 A1 WO2024098157 A1 WO 2024098157A1 CA 2023051502 W CA2023051502 W CA 2023051502W WO 2024098157 A1 WO2024098157 A1 WO 2024098157A1
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WO
WIPO (PCT)
Prior art keywords
ligneous
artificial turf
based particles
layer
belt
Prior art date
Application number
PCT/CA2023/051502
Other languages
English (en)
Inventor
Tina Kramer FERRAND
Eric Habib
Jason Smollett
Original Assignee
Tarkett Sports Canada Inc.
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 Tarkett Sports Canada Inc. filed Critical Tarkett Sports Canada Inc.
Publication of WO2024098157A1 publication Critical patent/WO2024098157A1/fr

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Classifications

    • EFIXED CONSTRUCTIONS
    • E01CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
    • E01CCONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
    • E01C13/00Pavings or foundations specially adapted for playgrounds or sports grounds; Drainage, irrigation or heating of sports grounds
    • E01C13/08Surfaces simulating grass ; Grass-grown sports grounds

Definitions

  • Artificial turf fields are composed of three primary components - from bottom to top: Shock pad, carpet, and infill. These components are generally assembled on top of a base of compacted stone.
  • the shock pad is optional and serves to convey much of the shock absorption performance of the turf field, required for the safety of those playing on the surface in the case of impact with the surface.
  • the carpet serves to mimic the blades of grass and root zone, conveying the softness and traction of the surface as well as many of the ball interaction properties.
  • the infill is generally constituted of at least two layers, the bottom layer of which serves to weight down and stabilize the carpets that it is laid onto, whereas the top layers serve as an additional interface layer to those playing on the field, conveying surface softness, friction, traction, and much of the mechanical properties of the field that are felt directly by the players.
  • the bottom, stabilizing infill is most often sand, serves to weigh down the turf carpet and keep it in place, as well as providing a more compact and solid base that conveys much traction to the overall turf assembly.
  • Other materials have also previously been used as stabilizing infill, but these remain limited in their pervasiveness due to the good performance, widespread availability, and low price of sand for this purpose.
  • the upper layers of infill have most often comprised styrene-butadiene rubber (SBR) particles due to the ready availability of end-of-life rubber from car tires, and in many places in the world this continues to be the most commonly used infill material due to shock absorption properties, and its ease of combination with other materials into a complete system.
  • SBR styrene-butadiene rubber
  • Other types of rubber such as ethylene propylene diene monomer (EPDM) rubber are also used for this purpose as they are generated as waste from other industries; these can be processed into performance infill to convey advantageous properties; other thermoplastics such as polyvinyl chloride (PVC) have also been used to similar effect.
  • Composite materials can be used that combine thermoplastics, elastomers, reinforcements and/or fillers to obtain further properties that are difficult to obtain with monolithic materials.
  • Cork has been the most common of this type of material used as a performance infill. Cork can provide mechanical performance characteristics, but its low density makes cork expensive to transport and can also lead to it floating off the fields in the case of heavy rain. Cork also includes relatively low wear resistance and limited availability due to long production times and limited growth region. Pulverized olive pits provide mechanical resistance, and are available at low cost, but exhibit a high coefficient of friction that is oftentimes adverse to player comfort. Coconut coir has good mechanical performance but requires constant watering to maintain its properties and performance. Mixed organic materials have also been used as performance infills.
  • a capitaous-belt com-based infill employs a shock pad to achieve a desired and/or proper shock absorption on the turf.
  • the ligneous-belt com- based infill is most often installed over a layer of sand wherein the sand acts as a stabilizing infill.
  • the sand performs as a ballast layer that weighs down the turf carpets and mitigates movement.
  • an infill composition for artificial turf fields comprises at least one layer of ligneous-belt com-based particles.
  • the neuous-belt com-based particles include a particle size distribution of capitaous-belt com-based particles with an initial dry size of approximately 0.5 to 5 mm and a final size of approximately 0.6 to 7 mm after wetting.
  • the infill can be installed according to a method of spreading a layer of ligneous-belt com-based particles over a carpet that is on a base of compacted stone, wherein the layer of ligneous-belt com-based particles includes or otherwise consists of dry particles. Thereafter, the layer of ligneous-belt com-based particles are sufficiently watered such that the dry particles are expanded after absorption.
  • the layer of ligneous-belt com-based particles are bmshed and the layer of ligneous-belt com-based particles are de-compacted such that the ligneous- belt com-based particles are evenly distributed over the carpet of the turf system.
  • a shock pad is most often employed to achieve a desired shock absorption of the pad.
  • FIG. 1 illustrates a turf carpet system having an infdl made of com- based material in accordance with some embodiments of the present disclosure.
  • FIG. 2 illustrates a turf carpet system having an infdl made of com- based material and sand in separate layers in accordance with some embodiments of the present disclosure.
  • FIG. 3 illustrates a turf carpet system having an infdl made of com- based material and sand in a mixed layer in accordance with some embodiments of the present disclosure.
  • An artificial turf system can use an infill material that includes material derived from the ligneous belt of a com cob(s).
  • a stabilizing layer such as sand or other sufficient material, is incorporated.
  • a shock pad is employed to achieve a desired shock absorption in accordance with a particular installation/purpose.
  • the infill material conveys many of the mechanical properties that are desired for the use as artificial turf infill and conveys performance advantages over the materials and methods described above.
  • the ligneous belt-based com infill material can be used in combination with a shock pad, carpet, and/or a stabilizing infill layer (e.g., sand) to make up the artificial turf system.
  • a shock pad e.g., carpet
  • a stabilizing infill layer e.g., sand
  • the artificial turf system using the described infill material, exhibits superior mechanical performance, a greater mechanical durability, easy availability and mitigates or otherwise avoids issues of floating away when subjected to large amounts of water.
  • this ligneous beltbased material of the com cob also exhibits behaviors that utilize and command unique methods for installation. Specifically, the material exhibits a significant amount of expansion upon first exposure to water due to the processing and drying method as an expanding, water absorbing, and resilient infill material.
  • the infill material can include a bottom layer of sand and a top layer of the ligneous-belt com-based infill material.
  • the ligneous-belt com-based infill material can be applied alone in a layer.
  • the ligneous-belt com-based infill material can be used in a single layer, for example, in aspects when the layer is 15 mm or less.
  • the ligneous-belt com-based infill material can be applied in 2 layers, for example, in installments that exceed 15 mm.
  • a desired installation includes a stabilizing infill layer (e.g., sand) along with an appropriate shock pad so as to achieve desired performance of the turf.
  • the ligneous-belt com-based infill material is compressed during its production. Therefore, once incorporated into a turf system, the infill material will be expanded via watering so as to regain or recover its original size/volume/shape. Through wetting, the ligneous-belt com-based infill material can swell (e.g., by approximately 33% in volume) after water is applied to it. Because of that expansion, an initial free pile length can be around 25-30 mm before applying water and expansion. It will be appreciated that the field can be watered naturally by rainfall, irrigation sprinkling the field, use of a water wagon, etc. such that the ligneous-belt com-based infill material will swell to regain its original volume.
  • the field can be treated with a brushing and decompaction treatment.
  • This brushing and decompaction treatment can take place after a waiting period, or immediately after applying the water.
  • the field can be sprinkled either by an irrigation system, by a water wagon or other suitable method.
  • a minimum amount water that should be applied such as one (1) liter per square meter.
  • the field can be maintained as a common field.
  • the biomass-belt com-based infill material can be of certain example specifications for use.
  • the ligneous-belt com- based infill material can use a particle size distribution of ligneous-belt com-based infill particles with an initial dry size of approximately 0.5 to 5 mm and a final (e.g., original or expanded) size of approximately 0.6 to 7 mm after wetting.
  • the ligneous-belt com-based infill articles can include a dry bulk density reduction of 20 to 90 % after the first time they are wet and expanded at the site of its use.
  • the ligneous-belt com-based infill particles can include a bulk density reduction between 30% and 50%. In still other embodiments, the neuous-belt com-based infill particles can include a bulk density reduction of 40%.
  • the ligneous-belt com-based infill material can be used in combination with a stabilizing infill (e.g., sand) and a shock pad. By way of example and not limitation, this combination can achieve a shock absorption of 55% to 70%, vertical deformation of 4 to 11 mm as measured by advanced artificial athlete (AAA), and a critical fall height greater than 1.3 meters, similar to a conventional third generation infilled artificial turf system.
  • a stabilizing infill e.g., sand
  • the amount of water and rate of addition can vary based on desired results.
  • the method can control expansion of the water absorbent ligneous-belt com-based infill material by the amount and rate of addition of water used to expand the ligneous-belt com-based infill.
  • a method of installation can include spreading the capitaous-belt com- based infill material on a field, watering, brushing, decompaction, and redistribution.
  • the watering can include a mass of water that is equal to twice the mass of dry expanding ligneous-belt com-based infill material.
  • the watering can include adding the total mass of water via a spreader to distribute the water evenly across the field or surface.
  • the ligneous-belt com-based infill material can be brushed and de-compacted between multiple water spreading steps.
  • Another method of installation can include a multiple step process to install the expanding ligneous-belt com-based infill material.
  • a first layer of expanding ligneous-belt com-based infill material can be spread evenly across the field.
  • the mass of the first layer corresponds to 10 to 75% of the total amount of expanding ligneous-belt com-based infill material.
  • the mass can be 30% to 60% of the total amount.
  • the mass can be 33% of the total amount.
  • the amount of water used to expand the ligneous-belt com-based infill material corresponds to 50% to 300% of the dry weight of the ligneous-belt com- based infill material. In other embodiments, the amount of water can be 175% to 225% of the dry weight. In yet another embodiment, the amount of water can be 200% of the dry weight of the ligneous-belt com-based infill material. While specific percentages, timeframes and measurements are outlined herein, it is to be appreciated that other aspects can exist that differ from those disclosed. As such, these additional aspects are to be included within the spirit and/or scope of this specification and claims appended hereto.
  • the method can include a period which the water is spread over the ligneous-belt com-based infill material for a time period of, for example 2 hours.
  • the method can include a waiting period of greater than 15 minutes after watering.
  • the waiting period can be greater than 4 hours before any further actions or steps.
  • the waiting period can be adjusted depending on the weather conditions including the amount of sunshine, wind speed, temperature, and relative humidity of the air.
  • the ligneous-belt com-based infill material can be brushed after watering. As needed or desired, the neuous-belt com-based infill material can be de-compacted. In some embodiments, the biomass-belt com-based infill material is preferentially de-compacted with most any suitable de-compactor that does minimal damage to the ligneous-belt com-based infill material and carpet. In some embodiments, a second or additional layer of dry expanding ligneous-belt com- based infill material is spread on top of the first or previous layer. The second layer of infill can be expanded with water.
  • the dry ligneous-belt com-based infill material can be hydrated and expanded using water or other liquids containing performance modifying solutes that alter the absorption characteristics, surface properties, or other performance related characteristics of the infill particles. While much of the aforementioned disclosure employs traditional watering techniques for hydration and expansion, other liquids, for example, those that include performance modifying solutes can be employed in conjunction with the ligneous-belt com-based infill.
  • the ligneous-belt com-based infill materials can be hydrated with water containing dissolved antifungal or antimicrobial compounds that convey those properties to the infill for slow release.
  • Another example would be hydration with a color dye solution meant to convey a specific color of the infill, as desired for aesthetic or functional purposes such as ultraviolet resistance and increased durability.
  • preservative agents that can be employed with the particles include, but are not limited to, Syzygium aromaticum extract oil, Cymbopogon genus extract oils, zinc salts such as zinc chloride, zinc pyrithione, zinc acetate, zinc sulfate; copper salts, such as copper sulfate, copper chloride, copper acetate, copper nitrate, or copper nanoparticles; silver salts, such as silver nitrate, silver chloride, or silver micro- or nanoparticles; chelating compounds, such as citrate salts, 2,3-dimercaptopropanol, and ethylenediaminetetraacetate.
  • embodiments are directed to using ligneous-belt com-based particles as a primary portion of the infdl for an artificial turf field.
  • Infill refers to material that is deposited over the turf backing 120 and forms a layer 105 around the turf fibers 125. Infill is interspersed between the turf fibers 125 rising out of the turf backing 120. Infill generally has a depth that covers a portion of the turf fiber (unexposed portion of the turf fiber) leaving part of the turf fiber extending above the infill (exposed portion of the turf fiber). While a stabilizing infill and/or shock pad is not shown in FIG. 1, it is to be appreciated that these can be employed in embodiments of the innovation as described above and below.
  • Infill 105 helps support the turf fibers 125 in an upright position and is used to provide traction and shock absorption.
  • the infill 105 comprises a specially designed layer of engineered ligneous-belt com-based particles.
  • the infill 105 can be installed using a method of spreading the ligneous-belt com-based infill material on a field, watering, brushing, de-compaction, and redistribution.
  • the infill 105 can use a particle size distribution of ligneous- belt com-based infill particles with an initial dry size of 0.5 to 5 mm and a final size of 0.6 to 7 mm that expands to after wetting.
  • the ligneous-belt com-based particles can include a dry bulk density reduction of 20% to 90% after the first time they are wet and expanded at the site of its use.
  • the ligneous-belt com-based particles can include a bulk density reduction between 30% and 50%.
  • the ligneous-belt com-based infill particles can include a bulk density reduction of 40%.
  • the ligneous-belt com-based infill material can be used in combination with a shock pad in order to achieve a desired shock absorption.
  • this combination of infill and shock pad can achieve a shock absorption of 57% or more than a conventional carpet or infill artificial turf system.
  • infill arrangements are contemplated. For example, two layer, three layers, or other arrangements are contemplated. For convenience, the present description primarily discusses two and three layer embodiments. Embodiments of the present disclosure are directed to providing com-based infill solutions. The materials that are discussed are primarily sand (as a stabilizing infill) and capitaous-belt com-based infill material but it should be understood that other materials can be included or substituted.
  • the infill material is directed to having the ligneous-belt com-based particles, in effect, replace crumb rubber infill materials.
  • the infill is devoid or substantially devoid of crumb rubber or similar materials.
  • one layer of the infill (e.g., one of the multiple layers in the infill) can be made entirely (100% by weight), substantially (e.g., 65% or higher or 75% or higher by weight), primarily (e.g., 50% or higher by weight), or predominantly (e.g., 45% or higher by weight, or a percentage by weight that is higher than the percentage by weight of any other particle or sand in the same layer) of the ligneous-belt com- based particles.
  • the infill can be only one layer, and the only layer can be made entirely (100% by weight), substantially (e.g., 65% or higher or 75% or higher by weight), primarily (e.g., 50% or higher by weight), or predominantly (e.g., 45% or higher by weight, or a percentage by weight that is higher than the percentage by weight of any other particle or sand in the layer) of the ligneous-belt com-based particles.
  • the ligneous-belt com-based particles can provide shock absorbency and traction.
  • the infill layer can include other organic materials or other materials in addition to or in place of those described herein.
  • the infill may include or comprise ligneous-belt com-based particles in a particular size range for dry application and expansion of particles after wetting.
  • the range of sizes can include a size distribution of com infill particles with an initial dry size of 0.5 to 5 mm and a final size of 0.6 to 7 mm to after wetting.
  • the ligneous- belt com-based particles can include a dry bulk density reduction of 20% to 90% after the first time they are wet and expanded at the site of its use, more preferably a bulk density reduction between 30% and 50%, or 40%.
  • the infill may comprise sand (e.g., in a layer) that is in a particular size range.
  • the range of sieve-sizes for sand may be from 20 to 50 (e.g., 0.841 mm-0.297 mm).
  • the infill may comprise the aforementioned biomass-belt com-based particles and sand (as a stabilizing layer) in separate layers (one overlaying the other) or intermixed as shown in FIGS. 2-3 respectively.
  • FIG. 2 depicts illustrative infill 205 comprising bambooous-belt com-based particles and sand in separate layers.
  • the first layer 210 (sequentially in the order of layers from bottom to top, where bottom is closest to the ground) is preferably a sand layer.
  • the infill may comprise capitaous-belt com-based particles of a desired engineered size and distribution.
  • the second layer 215 may comprise the aforementioned biomass-belt com-based particles, the aforementioned fine sand, or a combination thereof.
  • the second layer 215 includes both the ligneous-belt com-based particles and the sand, the biomass-belt com-based particles and the sand are preferably intermixed.
  • FIG. 3 depicts illustrative infill 305 comprising a layer 310 of ligneous-belt com-based particles and sand intermixed.

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Road Paving Structures (AREA)

Abstract

L'invention concerne une composition de remplissage pour des pelouses artificielles comprenant au moins une couche de particules comprenant des particules à base de ceinture ligneuse de maïs, les particules à base de ceinture ligneuse de maïs comprenant une répartition granulométrique de particules à base de ceinture ligneuse de maïs ayant une taille sèche initiale de 0,5 à 5 mm et une taille finale de 0,6 à 7 mm après mouillage. La composition de remplissage peut être installée selon un procédé consistant à étaler une couche de particules à base de ceinture ligneuse de maïs sur un tapis qui est disposé sur une base de pierre compactée, la couche de particules à base de ceinture ligneuse de maïs étant constituée de particules sèches ; à arroser la couche de particules à base de ceinture ligneuse de maïs de telle sorte que les particules sèches soient expansées après l'arrosage ; à brosser la couche de particules à base de ceinture ligneuse de maïs ; et à décompacter la couche de particules à base de ceinture ligneuse de maïs de telle sorte que les particules à base de ceinture ligneuse de maïs soient réparties uniformément sur le tapis.
PCT/CA2023/051502 2022-11-11 2023-11-10 Matériau de remplissage à base de rafle de maïs pour pelouses synthétiques WO2024098157A1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US202263424645P 2022-11-11 2022-11-11
US63/424,645 2022-11-11
US18/506,218 2023-11-10
US18/506,218 US20240159000A1 (en) 2022-11-11 2023-11-10 Corn cob based infill material for synthetic turf fields

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WO2024098157A1 true WO2024098157A1 (fr) 2024-05-16

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