New strategies towards the next generation of skin-friendly artificial turf surfaces

Tay, Sock P.

January 2016

The issue of skin friction related injuries has been one of the problems challenging the artificial sports turf industry. It has been identified by users as a major factor impeding acceptance of artificial turf at the professional level. However, information explaining the mechanisms for skin-turf abrasion is limited and little progress has been made, it appears, to derive an appropriate testing method for product approval or in evidence of improvement of the skin-friendliness of these products in sport surface surfaces. This research project focused on exploring the potential for improving the skin-friendliness of artificial turfs through a multi-faceted approach: identifying the contribution of the abrasive-components in modern artificial turf surfaces through mechanical testing; while critically evaluating currently available skin friction standards , evaluating strategies for polymer material modifications to reduce the skin-surface friction; and the designing of an appropriate bench-top set-up for the lab-based assessment of material skin-friendliness. The lack of understanding of skin-turf interaction was addressed by identifying the turf-component that has the greatest influence on the skin-turf friction with the mechanical device used in the current industry standard. The skin -turf frictional profiles of a series of third generation (3G) turf surfaces were examined, in combination with independent measurements of the silicone skin surface roughness pre- and post-friction testing. Results indicated that turf carpets without any infill material exhibited the highest frictional values while surfaces completely filled with either sand or rubber displayed similarly low frictional values, independent of infill type. Morphological measurements also showed the largest decrease in surface roughness for skin samples tested on carpet-only surfaces, indicating a smoothening effect via abrasion. This abrading effect is alleviated with the addition of infill to the surface, with fully-filled surfaces having the least damage to the skin s. This unprecedented study suggests that the carpet may have the largest influence on the overall frictional behaviour of an artificial turf surface narrowing down the turf component to be targeted when applying product improvements to address skin-friendly properties. The strategy of material surface modification was then employed, to study the effect of polyzwitterionic brushes on improving the skin-friendliness of the identified polypropylene substrate. To address the intended application for artificial turfs, a bench-top test was developed to investigate the frictional properties of the hydrated samples outside of commonly used aqueous environments, where an excess of lubricating water molecules is absent. Photo-grafted poly(sulfobetaine methacrylate) (pSBMA) brushes of various irradiation durations were prepared and the improvement in frictional properties was studied. Frictional measurements using silicone skin tips, under both dry and hydrated surface conditions, showed that the applied modification was capable of forming a stable lubrication layer in the absence of excess water, significantly reducing the coefficient of friction by up to 78.8 %. The pSBMA brushes also provided the additional advantage of antifouling exhibiting resistance towards pathogenic Staphylococcus aureus with almost zero surface colonization for well-grafted samples. The low skin -sample friction under ambient conditions and desirable fouling-resistance highlights the potential of pSBMA brushes as a modification strategy for achieving skin-friendly surfaces targeted at reducing the risk of skin abrasions. The tribological implications of counter-surface selection were investigated. Frictional assessments of the pSBMA-modified samples were carried out using standard steel tribo-tips, in addition to the skin tips used. Measurements with the skin tips showed that the hydrated pSBMA brushes were successful in reducing initial skin -sample friction though the effect diminishes with extended testing, attributed to the drying of the interfacial water. The standard steel tribo-tips were unable to reciprocate these results, returning consistently low frictional values regardless of extent of surface modification or hydration. These observations draw attention to the importance of counter-surface selection in frictional assessments, highlighting how appropriate test materials can identify characteristic surface properties while providing an interaction that simulates that of the intended application. The simple experimental set-up used may potentially be enhanced as an intermediate product qualification method in the manufacturing of skin-friendly artificial turf yarns.

635.9

KONSTGRÄSPLANER SOM MILJÖFARLIG VERKSAMHET : En undersökning av kommunernas arbete med att minska spridningen av mikroplaster / Artificial turfs as an environmentally hazardous activity : A survey of the work carried out by Sweden's municipalities to reduce the emissions of microplastics

Jonsson, Kajsa

January 2020

In Sweden exist about 1200 artificial turfs. Artificial turfs contain a layer of rubber granulates, which counts as microplastics and can emit to the environment. The emitted amount is uncertain but estimated to 475 tons/year. According to Swedish environmental code, artificial turfs can be classified as an environmental hazardous activity and the operators have a responsibility to reduce emissions. The purpose of this study was to investigate the work being done to reduce microplastic emissions from artificial turfs operated by Sweden’s municipalities and how it relates to the general rules of consideration in the environmental code. A web-survey was sent to all municipalities in Sweden. The result indicated that there is a high level of awareness of the problem among the municipalities. 68% have identified pathways for rubber granulates from the artificial turfs to the environment. Most common identified pathways were players, via stormwater and snow clearance. 87% have taken protective measures to reduce emissions. Most common measures taken were hard surface around the turf, granulate traps/filter in stormwater wells and collection areas for snow. Some municipalities are also testing and investigating alternative infill material. A majority were aware of the Swedish environmental protection agency’s guidance. The general rules of consideration were applicable to reduce emissions of microplastic. The reuse of rubber granulates when refilling the turfs and the investigation for alternative infill material could increase. Knowledge and insight among the operators, players and maintenance are key factors to limit the emissions along with proper protective measures.

artificial turf

microplastic

infill

granulates

Natural Sciences

Naturvetenskap

The Fate of Methicillin-Resistant Staphylococcus aureus in a Synthetic Field Turf System

Keller, Marcus

January 2013

No description available.

Microbiology

MRSA

turf

synthetic turf

artificial turf

infill

Advanced measurement for sports surface system behaviour under mechanical and player loading

Wang, Xinyi

January 2013

This research project has investigated the mechanical behaviour of artificial turf surface systems used for sports under a range of real player movements, and the contribution of component layers to the overall system response by developing advanced measurement systems and methods. Artificial turf surface systems are comprised of a number of different materials and commonly with several layers, all of which contribute to their composite behaviour. During sports movements a player loads the surface, resulting in deformation that can change the surface behaviour, which in turn modifies the player biomechanical response. Improving the understanding of surface response to actual player loading is important for developing enhanced products for improving play performance. Likewise, by improving knowledge of surface effects on players, the understanding of injury risk can be improved. However, there is currently no published research to measure and analyse the behaviour of artificial turf system during real player locomotion. This research was undertaken to address this current lack of knowledge within the interaction between player and sports surface regarding the effects of player loading on the mechanical behaviour of artificial turf systems. In addition to support player loading regime, mechanical behaviour of hockey and third generation artificial turf surface systems and their component shockpad layers (a rubber shreds bonded shockpad and a polyurethane foam shockpad) was examined through dynamic cyclic compressive loading using an advanced material testing machine in laboratory environment. Each layer and carpet-shockpad system was subjected to controlled loading designed with previous biomechanical data at various loading frequencies (0.9 Hz, 3.3 Hz and 10 Hz) and under two different contact areas (50 mm and 125 mm diameter) to simulate aspects of player walking, running and sprinting. All layers and surface systems tested showed nonlinear stress-strain behaviour with hysteresis. Increasing the contact area resulted in reduced surface vertical deflection and more linear response. Increasing the loading frequency led to stiffer response in the lower stress range (< 400 kPa) for all surface systems. The third generation artificial turf systems showed also an increase in stiffness at higher stress range ( > 600 kPa) and a decrease in maximum strain as the loading frequency increased. Hysteresis loops obtained at different loading frequencies indicated that the amount of energy lost at the same peak load of 1900 N in each surface system decreased with an increase in loading rate. Player loading regime was performed to quantify the load/stress and the resulting surface deformation/strain under subject loading. Measurement systems including motion capture system, force plate and high speed were developed to characterise the response behaviour in a novel way. The mechanical behaviour of artificial turf surface systems under three player movement patterns (heel-toe walking, forefoot running and forefoot single leg landing) was measured. Boot-surface contact area of each movement varied during the stance. The heel-toe walking results indicated that the maximum applied stress and surface strain occurred in very early stance (first 10%) when the boot-surface contact area was small. For forefoot running and landing, the peak surface strain occurred around mid-stance concurrent with the time of peak applied stress. The maximum strain measured under running was smaller than under landing. A thin-film pressure sensing mat was used in both mechanical and player loading regimes and proved to be a useful tool for evaluating the pressure distributions and contact areas at different interfaces of the surface system. The applied stress on surface was observed to greatly reduce with depth over increasing contact area through the surface systems. Although the average pressure was reduced, pressure distribution contour showed directly under the surface load area the pressure at depth was still relatively large and that outside of this area the pressure was much lower. A comparison of the mechanical behaviour of artificial turf systems in terms of compressive strain, modulus of elasticity, stress distribution and energy loss under mechanical and player loading was evaluated. Key loading parameters in different loading regimes and their influence on surface system response were determined. The structure and material intrinsic properties of shockpad were considered to further explain the observed surface system behaviour. Two mathematical models were used to fit through the experimental data and found to be able to describe the loading behaviour. A breakthrough in understanding of the effects of real player loading on the mechanical behaviour response of artificial turf systems, and the contribution of the components to the whole system response has been achieved through the development of advanced measurement techniques.

798

Risk factors for injury in men´s professional football

Kristenson, Karolina

January 2015

This thesis includes four papers based on three different prospective cohort studies on injury characteristics in men’s professional football. The same general methodology was used in all papers. Time-loss injuries and player individual exposure was registered for match and training separately. The general aim was to investigate potential internal and external risk factors for injury, with a focus on age, playing position, time in professional football, playing surface (artificial turf and natural grass), changes between surfaces and climate; and to evaluate the study methodology. Paper I was based on data collected between 2001 and 2010 from 26 top professional clubs in Europe; the UCL injury study. In total, 6140 injuries and 797 389 hours of exposure were registered. A decreased general injury rate was observed for newcomers compared with established players (hazard ratio (HR), 0.77; 95% CI 0.61-0.99). Using goalkeepers as a reference, all outfield playing positions had significantly higher age-adjusted injury rates. Using players aged ≤ 21 years as a reference, the overall adjusted injury rate increased with age, with a peak injury rate among players aged 29 to 30  years (HR, 1.44; 95% CI, 1.24-1.68). Paper II and Paper III are based on data collected during two consecutive seasons, 2010 and 2011, in the Swedish and Norwegian male first leagues. In total, 2186 injuries and 367 490 hours of football exposure were recorded. No statistically significant differences were found in acute injury rates on artificial turf (AT) compared with natural grass (NG) during match play (rate ratio, 0.98, 99% CI 0.79-1.22) or training (rate ratio 1.14, 99% CI 0.86-1.50) when analysing at the individual player level. However, when analysing at the club level, clubs with AT installed at their home arena had a significantly higher acute training injury rate (rate ratio 1.31, 99% CI 1.04-1.63) and overuse injury rate (rate ratio 1.38, 99% CI 1.14-1.65) compared to clubs with NG installed at their home venue. No association was found between frequent surface shifts and subsequent overuse injury risk (risk ratio 1.01, 95% CI 0.91-1.12). Analyses on the total cohort showed no difference in injury rates between clubs in the two climate zones (total rate ratio 1.01, 95% CI 0.92-1.10). Data included in Paper IV were collected during two consecutive seasons 2008 and 2009. During this period, two Norwegian elite football clubs were concurrently included in two research groups’ surveillance systems. The capture rate for match injuries was similar between the two audits, while the capture rate for training injuries was slightly higher with individual-based exposure recording. The inter-rater agreement in injury variable categorisations was in most aspects very high.

Age

artificial turf

cohort study

elite

epidemiology

overuse injury

soccer

surface

sporting injuries

playing position

En giftfri konstgräsplan

Eriksson, Alexander, Eriksson, Andreas, Nyström, Ville, Odelgard, Kajsa, Pierrou, Clara

January 2017

EPDM and R-EPDM granules are used as infill on all of the artificial football fields in Uppsala. The aim of the study was to establish possible health risks related to the infill for players on artificial turf in Uppsala. Furthermore the aim was to investigate the possible ecotoxicological effect on surrounding waterways by the infill material. A comparative analysis concerning health and ecotoxicological effects for these materials was carried out. Eight different granules from the artificial turf in Uppsala was collected and analysed using TGA. The TGA results were modelled in two different scenarios to show possible air concentrations of 100-300 µg/m3 VOC over artificial football fields with EPDM granules. Calculations based on the tolerable daily dose of substances found in the granules were carried out. The conclusions of the study shows that the EPDM granules used today are safe from a health perspective. SBR granules from recycled tires does not constitute to any health risks either. The ecotoxicological risk for surrounding waterways is low. EPDM is less cost and energy efficient compared to SBR from recycled tires. Reduction of granular spill is very important from an environmental and cost point of view, regardless of the choice of material for artificial turf.

Artificial turf

granules

EPDM

R-EPDM

SBR

VOC

oral intake

health

Materials Chemistry

Materialkemi

En giftfri konstgräsplan

Nyström, Ville, Odelgard, Kajsa, Pierrou, Clara, Eriksson, Andreas, Eriksson, Alexander

January 2017

EPDM and R-EPDM granules are used as infill on all of the artificial football fields in Uppsala. The aim of the study was to establish possible health risks related to the infill for players on artificial turf in Uppsala. Furthermore the aim was to investigate the possible ecotoxicological effect on surrounding waterways by the infill material. A comparative analysis concerning health and ecotoxicological effects for these materials was carried out. Eight different granules from the artificial turf in Uppsala was collected and analysed using TGA. The TGA results were modelled in two different scenarios to show possible air concentrations of 100-300 µg/m3 VOC over artificial football fields with EPDM granules. Calculations based on the tolerable daily dose of substances found in the granules were carried out. The conclusions of the study shows that the EPDM granules used today are safe from a health perspective. SBR granules from recycled tires does not constitute to any health risks either. The ecotoxicological risk for surrounding waterways is low. EPDM is less cost and energy efficient compared to SBR from recycled tires. Reduction of granular spill is very important from an environmental and cost point of view, regardless of the choice of material for artificial turf.

Artificial turf

granules

EPDM

R-EPDM

SBR

VOC

oral intake

health

Materials Chemistry

Materialkemi

Sustainability of Artificial Turf Fields : Comparative life cycle assessment of artificial and natural turf fields

Säberg, Mikael

January 2021

Soccer accounts for a third of the Swedish sports movement with 3 503 fields of both natural and artificial turf. The European Union will make a decision in 2021 on how to handle the issue of rubber performance infill. This infill can be found in artificial turf fields and are used for performance properties. The problem with this infill is the microplastics that spreads into the nature which is considered as toxic. Because of this the EU have decided to either ban or provide mandatory rules to reduce the spread of rubber performance infill. The north and the majority of Sweden’s climate is not adapted for play of soccer on natural turf according to FIFA, and EU want to ban or provide mandatory rules for artificial turfs. This action from the EU can perturb the entire Swedish sports movement since soccer accounts for a third of that movement. This study was therefore created to show if artificial turf fields are as bad for the environment as rumours has said compared with the natural turfs. To investigate this, a life cycle assessment (LCA) was performed regarding the global warming potential (GWP) and embodied water consumption for three different field types: an artificial turf field with recycled SBR, an artificial turf field with cork and a natural turf field. The result visualised that a natural turf field had the highest embodied water consumption and the highest impact on the GWP of a ten-year life cycle while the artificial turf field with recycled SBR had the least embodied water consumption and the least impact on the GWP. The findings of this LCA were that Sweden for the moment is dependent on artificial turf and the rubber performance infill, since the material properties are the best adapted to their climate. Therefore, a ban would be a risk for the Swedish sports movement. It was also revealed that natural turf fields in Sweden consumes at least 50 % municipal drinking water when irrigate. The high GWP impact came from the production of fertilisers (NPK). This report has shown how artificial turf and natural turf can work together in an industrial symbiosis by making the artificial turf field constructed to collect rainwater and use that water to irrigate the natural turf with.

artificial turf

natural turf

life cycle assessment

infill materials

water consumption

Environmental Management

Miljöledning

Spreading of microplastics from artificial turf via stormwater / Spridning av mikroplaster från konstgräsplaner via dagvatten

Lundström, Johanna

January 2019

På senare tid har mikroplaster i hav och sjöar uppmärksammats som ett potentiellt stortmiljöproblem. Idag finns mikroplaster spridda över hela världens vatten från polerna till ekvatorn.År 2016 uppmärksammades konstgräsplaner som den nästa största källan till spridning avmikroplaster till sjöar och vattendrag i Sverige [1]. Fotboll är Sveriges nationalsport och är densporten som står för flest aktivitetstimmar i Sverige. Konstgräs har gjort det möjligt för fler barnoch ungdomar att få fler speltimmar och idag spelar 90 % av alla fotbollsspelare på konstgräs [2].De olika spridningsvägarna för mikroplaster från konstgräsplaner undersöktes med fokus påspridningsvägen via dagvatten. Det finns fler olika reningsmetoder för dagvatten innehållandemikroplaster, en av dessa är granulatfällan, en filterpåse som placeras i en dagvattenbrunn för attfånga upp granulat och konstgräsfibrer som sprids från konstgräsplanen till dagvattenbrunnen.Syftet med denna studie var att optimera reningsmetoden granulatfälla utifrån möjligavattenflöden och dess effektivitet i att fånga upp mikroplaster. Detta undersöktes genomframtagandet av en vattenflödesmodell vid konstgräsplaner med variationer i konstruktion ochgenom fältstudier av granulatfällans effektivitet vid två konstgräsplaner i Storstockholm.Det regn som undersöktes i vattenflödesmodellen var extremregn för ett 10 års regn under 10minuter. Detta för att hitta det maximala flöde granulatfällorna kommer behöva klara av. Vilkavattenflöden som nådde dagvattenbrunnarna var beroende på antalet dagvattenbrunnarplacerade runt konstgräsplanen, i vilket område i Sverige som konstgräsplanen var placerad, detvill säga hur mycket regn som kom, och konstgräsplanens infiltrationsförmåga.Vattenflödesmodellen fungerar som en mall för möjliga vattenflöden vid en specifik plats i Sverigeoch en viss konstruktion av konstgräsplan.De konstgräsplaner som var med i fältstudierna var Skytteholms IP i Solna och Spånga IP iStockholm. Vid varje konstgräsplan placerades 6 granulatfällor med två filterpåsar på varje fälla,den inre med större maskor och den yttre med mindre maskor. Kombinationerna var 200 μm med100 μm, 200 μm med 50 μm och 100 μm med 50 μm. Totalt fångades 10,3 kg mikroplast vidSkytteholms IP och 1,5 kg vid Spånga IP under de 49 dygn granulatfällorna var utplacerade. Avden totala mängden mikroplast viktmässigt i varje granulatfälla fanns minst 99 % i den inrefilterpåsen och maximalt 1 % i den yttre filterpåsen, det vill säga i storleksfraktionen mellan denyttre och den inre filterpåsen.Slutsatserna från denna studie är att vattenflödet till dagvattenbrunnarna placerade runtkonstgräsplaner kan variera mycket på grund av hur konstgräsplanen är konstruerad. Det berorframförallt på konstgräsplanens infiltrationsförmåga och antal dagvattenbrunnar runtkonstgräsplanen. Utifrån de teoretiska vattenflödena och fältstudierna rekommenderas att enfilterpåse med maskstorlek 200 μm används i granulatfällan. Detta utifrån att den inre filterpåsenfångade minst 99 % av de mikroplaster som nådde granulatfällorna, som var större än 50 μm, ochökad risk för igensättning och tillväxt av biofilm på filterpåsarna med mindre maskor. Vidarestudier bör genomföras på granulatfällans vattenflöde över tid, mikroplaster mindre än 50 μm,IIandra spridningsvägar för mikroplaster från konstgräsplaner, förbättrade konstruktioner avkonstgräsplaner och förbättrat underhållningsarbete för att minska spridningen av mikroplasterfrån konstgräsplaner. / In the recent years microplastics in the marine environment has been recognized as a potentiallyimportant environmental issue. Today there are microplastics spread in the waterbodies all overthe world, from the equator to the poles in south and north. In 2016 artificial turf was labeled thesecond largest source of microplastics to the marine environment in Sweden [1]. Football is thenational sport of Sweden and accounts for the majority of the activity hours among the youth inSweden. The artificial turf has made it possible for more children to play football and for them toget more hours on the field. Today about 90 % of the football players play on artificial turf [2].The microplastics pathways to the nature and the marine environment were studied andtreatment methods were developed. One of these methods is the so called granule trap, a filterbag which is placed in a stormwater drainage well to catch the rubber granulates and the artificialturf fibers which can be spread from the artificial field to the drainage system. The aim of thisstudy was to optimize the granule trap for possible waterflows to the stormwater drainage welland its efficiency to catch microplastics. This was researched through field studies of the efficiencyof the granule trap at two artificial turfs in Stockholm and the development of a waterflow modelof an artificial turf with varying construction.The rainfall which was used in the waterflow model was the 10-year storm with a duration of 10minutes. This to find the maximum waterflow the granuletraps must manage. The waterflows tothe stormwater drainage well were dependent on the number of wells placed around the artificialturf, in which area of Sweden the football field was placed, in other words the amount of rain thatfell, and the infiltration capacity of the artificial turf. The waterflow model works as a templatefor possible waterflows at an artificial turf with a certain construction and at a certain location inSweden.The artificial turfs which were examined in the field studies were Skytteholms IP in Solna andSpånga IP in Stockholm. At each football field 6 granuletraps were placed, each loaded with twofilter bags, the inner with larger sized mesh and the outer with smaller sized mesh. The mesh sizecombinations were 200 μm with 100 μm, 200 μm with 50 μm and 100 μm with 50 μm. atSkytteholms IP a total amount of 10.3 kg microplastics were caught and at Spånga IP a total of 1.5kg microplastics were caught during the 49 days the granuletraps were placed at the footballfields. Out of the total amount of microplastics in each granuletrap at least 99 % by mass was inthe inner filter bag and maximum 1 % by mass was in the outer filter bag, in the size fractionbetween the outer and the inner filter bag..In conclusion this study shows that the waterflow to the stormwater drainage wells placed aroundthe artificial turfs vary a lot depending on the construction of the artificial turf. Foremost itdepends on the infiltration capacity of the artificial turf and the number of stormwater drainagewells around the field. With regards to the waterflows from the waterflow model and the resultsfrom the field studies the recommended mesh size for the filter bags is 200 μm. This since at least99 % by mass of the microplastics, which were larger than 50 μm, that reached the granule trapsIVwere trapped in the inner filter bag and the elevated risk of clogging and biofilm growth on thefilter bags with smaller mesh size. Further studies should be conducted on the waterflow throughthe granuletraps over time, microplastics smaller than 50 μm, other pathways for themicroplastics away from the artificial turf, improved constructions of artificial turfs and improvedmaintenance on the artificial turfs to reduce the risk of spreading of microplastics from artificialturfs.

Microplastics

Artificial turf

Granule trap

Granulate

Waterflows

mikroplast

konstgräsplan

granulatfälla

granulat

vattenflöden

Chemical Engineering

Kemiteknik

Mikroplaster från konstgräsplaner : Orsaker till spridning av mikroplaster samt en kvalitativ analys av spridningen till dränerings- och dagvattenbrunnar / Microplastics from artificial turf fields : Reasons for spreading of microplastics and a qualitative analysis of the spread to drainage and stormwater wells

Regnell, Fredrick

January 2017

Mikroplaster och dess miljöeffekter är ett forskningsområde under utveckling. Provtagning och analysmetoder försvåras av att mikroplaster kan komma från olika råvaror, vilket innebär att dess innehåll, partikelstorlek samt densitet kan variera. Det är däremot tydligt att mikroplaster är ett problem i marina miljöer då intag och ackumulering av mikro- och makroplaster har registrerats i ryggradslösa djur, fiskar, däggdjur och fåglar. Mikroplaster kan påverka bland annat matsmältningen och reproduktionen för vattenlevande djur. Mikroplaster har även registrerats i föda som är relevant för människor, men vilka effekter mikroplaster har på människor är ännu oklart. I en rapport från år 2017 uppskattade Svenska Miljöinstitutet (IVL) konstgräsplaner till att vara den näst största kvantifierade källan till spridning av mikroplaster till miljön med 1638 – 2456 ton per år, efter slitage från däck och vägar. Fotboll är en av Sveriges populäraste sporter och antalet konstgräsplaner i landet uppgick år 2016 till 1336 stycken. Till följd av att konstgräsplaner anses som en viktig källa till spridning av mikroplaster är det viktigt att utröna orsakerna till hur och varför mikroplaster sprids från konstgräsplaner och även vilka åtgärder som kan sättas in för att minska spridningen. Syftet med denna studie är att identifiera orsakerna till spridning av mikroplaster samt att presentera åtgärder som kan minska den totala spridningen av mikroplaster från konstgräsplaner. Metodiken utgick från tidigare studier av mikroplaster i vattenmiljö och vattenprover inhämtades från två konstgräsplaners dräneringsbrunnar och från en konstgräsplans lysimetrar, vilka har samlat upp vatten som har infiltrerat genom planen. Utöver detta har även fältstudier med observationer utförts vid två konstgräsplaner och samtal med driftsansvariga har bidragit med ytterligare relevant information om hur mikroplaster kan spridas. Resultaten visar att mikroplaster sprids från konstgräsplaner och att de identifierade orsakerna till spridningen, utan inbördes storleksordning, främst är: Aktivitet på planen Borstning av planen Snöröjning Regn (vilket innebär infiltration genom planen samt ytavrinning) Dessa orsaker, samt möjliga spridningsvägar för mikroplaster från en konstgräsplan till omgivningen, har visualiserats i en konceptuell modell, figur 11. Modellen har två systemgränser; det inre systemet utgörs av själva konstgräsplanen, medan det yttre systemet utgörs av närområdet runt omkring planen och kan likställas med idrottsanläggningen. Det är endast mikroplaster som sprids från det yttre systemet ut till omgivningen som bedöms kunna ha ekologiska konsekvenser. Okulära mikroskopstudier av vattenprover från dräneringsbrunnar visade på förekomst av mikroplaster. Kvantifiering av mängden fast material som kan nå dräneringsbrunnar, där mikroplaster utgör en okänd andel, uppgick till maximalt 340 – 370 kg per år och konstgräsplan med måtten 105m×65m. Mängden mikroplaster som maximalt kan infiltreras genom en konstgräsplan ner till dess dränering kvantifierades till 0,003 kg per år och konstgräsplan med måtten 105m×65m. Detta indikerar att det kan krävas mer öppna transportvägar, exempelvis öppna brunnar, för att mikroplaster ska kunna nå dräneringsbrunnar i en större viktmässig omfattning. Kvantifieringen av övriga orsaker till spridning av mikroplaster från konstgräsplaner till omgivningen är osäker, men försiktiga uppskattningar visar på att de är viktmässigt omfattande. För att mäta och säkerställa antalet partiklar som sprids från konstgräsplaner skulle mer omfattande provtagningar och analyser behöva genomföras. Konkreta åtgärder som kan tillämpas för att minska den totala spridningen av mikroplaster från konstgräsplaner är att borsta av kläder och skor innan planen eller anläggningen lämnas, informera personer som uppehåller sig vid planerna om problematiken, täcka för brunnar vid driftsaktiviteter, strategisk hantering av snöröjning, återföra granulat från anläggningen till själva planen, installera filter i brunnar samt att tömma brunnar på vatten och material. För att sätta problemet med mikroplaster från konstgräsplaner i sitt sammanhang så är det viktigt att förstå problemet i sin helhet. Vidare studier föreslås fokusera på att kvantifiera ovan nämnda orsaker till spridning av mikroplaster från konstgräsplaner, samt att kartlägga och kvantifiera spridningen utifrån de olika spridningsvägarna. / Microplastics and its environmental impacts is a research area under development. Sampling and analysis methods are complicated by the fact that microplastics may come from different raw materials, which means that its content, particle size and density may vary. It is clear that microplastics is a problem in marine environments as intake and accumulation of micro- and macroplastics have been recorded in invertebrates, fish, mammals and birds. The microplastics may affect, among other things, the digestion and reproduction of aquatic animals. The microplastics have also been recorded in foods that are relevant to humans, but what effects microplastics have on humans is still unclear. In a report from 2017, the Swedish Environmental Research Institute (IVL) estimated artificial turf fields to be the second largest quantified source for spreading the microplastics to the environment with 1638 - 2456 tons per year, after wear of tire and roads. Football is one of Sweden's most popular sports and the number of artificial turf fields in the country in 2016 reached 1336. Due to the fact that artificial turf fields is considered an important reason for the spreading of microplastics, it becomes important to investigate the reasons why and how microplastics are spread from artificial turf fields and also what measures can be taken to reduce the spread. The purpose of this study is to identify the reasons why microplastics are spread, as well as to present measures that can reduce the overall spread of microplastics from artificial turf fields. The methodology is based on previous studies of microplastics in aquatic environments and water samples were collected from drainage wells that belonged to two artificial turf fields and from a “water-infiltration-sampler” from a third field. In addition, field studies with observations have been carried out at two other artificial turf fields, and conversations with maintenance personal have provided additional relevant information on how microplastics can be spread. The results show that microplastics are spread from artificial turf fields and the identified reasons for this spreading, without specific order of magnitude, are mainly: Activity on the field Brushing of the fields Snow plowing of the fields Rain (which means infiltration through the field as well as surface runoff) These causes, as well as possible pathways for the spreading of microplastics from an artificial turf field to the surroundings, have been visualized in a conceptual model, Figure 11. The model has two system boundaries; the inner system consists of the field itself, while the outer system is the direct area around the field and can be equated with the sports facility. It is only microplastics that are spread from the outer system to the environment which is considered to cause ecological consequences. Ocular microscopy studies of water samples from drainage wells showed presence of microplastics. Quantification of the amount of solids that can reach the drainage wells, where microplastics constitute an unknown proportion, amounted to a maximum of 340 – 370 kg per year and artificial turf field measuring 105m×65m. The maximum amount of microplastics that can infiltrate through an artificial turf field down to its drainage system was quantified to 0,003 kg per year and artificial turf of 105m×65m. This indicates that more open transport routes, such as open wells, could be needed to allow microplastics to reach drainage wells to a greater extent. The quantification of other causes for the spreading of microplastics from artificial turf fields to the environment area is uncertain, but careful estimations show that they are weighty comprehensive. To measure and secure the number of particles that are spread from artificial turf fields, more extensive sampling and analysis would have to be carried out.

Microplastics

Artificial turf

Infill

Granulate

Football

Mikroplast

Konstgräs

Fyllmaterial

Granulat

Fotboll

Environmental Sciences

Miljövetenskap