Conference Paper

Nitrogen Inflation for Passenger and Light Truck Tires

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Abstract

Nitrogen as an inflation gas for passenger car and light truck tires use is widely available commercially. Consumers are confronted with a bewildering selection of offerings, and suppliers tout the purity of their nitrogen generation systems and effectiveness of using the gas in place of air. This paper develops models for the initial tire nitrogen purity, the inflation pressure loss rate, and the evolution of the nitrogen gas purity in the tire as a function of the gas used to top off the tire over its life. A series of simulations using the basic model is developed for air and various purities of nitrogen initial inflation with monthly top-off using air or various purities of nitrogen. The initial inflation pressure loss rate is shown as a function of the tire’s initial nitrogen purity. This paper proposes the use of the total oxygen passing through the tire over its lifetime as a metric for evaluation of various inflation schemes. This metric is developed for several of the popular available nitrogen inflation purities using both air and nitrogen as a top-off gas

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... Be to, vanduo, esantis ore, gali pakeisti skysčio pavidalą į garus esant atitinkamai temperatūrai. Esant aukštesniam darbinės temperatūros slėgiui padangose pripūstas oras gali padidėti nuo 0,26 Psi esant 600 F iki 2,89 PSI esant 1400 F (Daws, 2010). ...
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Eksploatuojant keleivines transporto priemones degalų suvartojimo ekonomiškumas siejamas su tuo, kaip yra valdoma transporto priemonė. Ekonomiškas transporto priemonės valdymas priklauso nuo variklio, transmisijos, aerodinaminio pasipriešinimo bei transporto priemonės riedėjimo. Variklio, transmisijos ir aerodinaminiai nuostoliai paprastai yra siejami su šių transporto priemonės dalių konstrukcija, o riedėjimo nuostoliai yra susiję su transporto priemonės padangomis ir tai yra vienintelė transporto priemonės dalis, turinti tiesioginį sąlytį su keliu. Pripūstų padangų pasipriešinimas riedėjimui yra svarbus atsparumo komponentas, lemiantis transporto priemonės judėjimą ir prisidedantis prie transporto priemonės degalų sąnaudų sumažėjimo. Daugelis tiriamųjų darbų buvo sutelkta į tai, kaip įvairūs padangų parametrai (pvz., apkrova, dujų slėgis padangoje ir transporto priemonės judėjimo greitis) lemia pasipriešinimą riedėjimui ir degalų sąnaudų ekonomiškumą. Naujausi tyrimai rodo, kad padangos, pripūstos azoto dujų, gali palaikyti tinkamą slėgį ir sumažinti gumos susidėvėjimą. Todėl šio tyrimo tikslas yra ištirti azoto dujomis pripūstų padangų naudojimo įtaką transporto priemonės saugumui, eksploatacinių savybių pagerinimui ir eksploatacinių išlaidų sumažinimui.
Article
All tires fail due to interior oxidative deterioration, structural defects from manufacturing errors, improper tire design, road hazards, and exterior cracking caused by ozone and ordinary oxidation, most important being interior oxidative deterioration. This failure cause, while being most important, is least understood and appreciated. Oxidative deterioration of tires starts within the interior gas chamber, which acts triply for ride cushioning, as the reservoir of heat generated by the running tire, and as the vessel which contains oxygen to effect the tire's destruction. Arrhenius' law and the mass action law of chemical reactions are followed in that oxidative deterioration is governed by heat (temperature) and oxygen concentration. Since hysteresis (running temperature) can only be controlled within limits, lowering the oxygen concentration of the inflating gas is the only remaining way of inhibiting oxidative deterioration of tires, which is a cumulative effect of time, temperature and interior oxygen concentration. Five carefully controlled passenger and truck tire tests were run during the past eighteen months to investigate oxidation phenomena. In each test, one half the test sample was inflated with ordinary air, the other half with an inert gas to reduce the oxygen concentration. Over 2.5 million tire miles were run in these five tests. A sixth test involving over eighty truck tires was run more than 6.5 million tire miles during the past 36 months to observe the oxidative effect of air inflation upon inner tubes and tire body deterioration. All six tests show strikingly that oxygen-free inflation gas has a profound and major beneficial effect upon overall tire endurance and upon tire wear. Actual performance data show tire endurance of passenger tires to be improved an average of 22 per cent when oxygen concentration is reduced to 0.6 per cent and wear improvement of 15 per cent at a point where tires were only 64 per cent worn.