ENVIRONMENTAL PERFORMANCE OF RETREADED TIRES

Regulations R(EC)661/2009 and R(EC)1222/2009 established environmental requirements for new tires and their labeling, not applicable in principle to retreaded tires. However, in anticipation of future revisions, different studies were promoted, mainly oriented to truck tires, the main market for retreading. Two lines of research were opened at UMH, focused respectively on the study of rolling resistance and rolling noise.

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Tire-Road Interactions — Harmony or Conflict?

Tire Science and Technology ◽

10.2346/1.2141676 ◽

1989 ◽

Vol 17 (1) ◽

pp. 66-84

Author(s):

A. R. Williams

Keyword(s):

Rolling Resistance ◽

Major Effect ◽

Road Surface ◽

Interactive Effects ◽

Central Theme ◽

Water Drainage ◽

The Road ◽

Truck Tires ◽

Road Surfaces ◽

Tire Wear

Abstract This is a summary of work by the author and his colleagues, as well as by others reported in the literature, that demonstrate a need for considering a vehicle, its tires, and the road surface as a system. The central theme is interaction at the footprint, especially that of truck tires. Individual and interactive effects of road and tires are considered under the major topics of road aggregate (macroscopic and microscopic properties), development of a novel road surface, safety, noise, rolling resistance, riding comfort, water drainage by both road and tire, development of tire tread compounds and a proving ground, and influence of tire wear on wet traction. A general conclusion is that road surfaces have both the major effect and the greater potential for improvement.

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Tread Depth Effects on Tire Rolling Resistance

Tire Science and Technology ◽

10.2346/1.2135235 ◽

2001 ◽

Vol 29 (3) ◽

pp. 134-154 ◽

Cited By ~ 5

Author(s):

J. R. Luchini ◽

M. M. Motil ◽

W. V. Mars

Keyword(s):

Finite Element Analysis ◽

Common Knowledge ◽

Rolling Resistance ◽

Test Method ◽

Tire Model ◽

Element Analysis ◽

Truck Tires ◽

The Finite Element Analysis ◽

Equilibrium Test ◽

Depth Effects

Abstract This paper discusses the measurement and modeling of tire rolling resistance for a group of radial medium truck tires. The tires were subjected to tread depth modifications by “buffing” the tread surface. The experimental work used the equilibrium test method of SAE J-1269. The finite element analysis (FEA) tire model for tire rolling resistance has been previously presented. The results of the testing showed changes in rolling resistance as a function of tread depth that were inconsistent between tires. Several observations were also inconsistent with published information and common knowledge. Several mechanisms were proposed to explain the results. Additional experiments and models were used to evaluate the mechanisms. Mechanisms that were examined included tire age, surface texture, and tire shape. An explanation based on buffed tread radius, and the resulting changes in footprint stresses, is proposed that explains the observed experimental changes in rolling resistance with tread depth.

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Commercial Trailer Tires: Tire Inflation and Its Effect on Rolling Resistance, Fuel Economy, and Tire Footprint

Tire Science and Technology ◽

10.2346/tire.15.430201 ◽

2015 ◽

Vol 43 (2) ◽

pp. 144-162

Author(s):

Al Cohn

Keyword(s):

Fuel Economy ◽

Rolling Resistance ◽

Maintenance Cost ◽

Wear Loss ◽

Truck Tires ◽

Footprint Analysis ◽

Subsequent Loss ◽

Resistance Data

ABSTRACT Maintaining proper tire inflation is the number one issue facing commercial fleets today. Common, slow-leaking tread area punctures along with leaking valve stems and osmosis through the tire casing lead to tire underinflation with a subsequent loss in fuel economy, reduction in retreadability, tread wear loss, irregular wear, and increase in tire-related roadside service calls. Commercial truck tires are the highest maintenance cost for fleets second only to fuel. This article will examine tire footprint analysis, rolling resistance data, and the effect on vehicle fuel economy from tires run at a variety of underinflated, overinflated, and recommended tire pressures. This analysis will also include the tire footprint impact by running tires on both fully loaded and unloaded trailers. The footprint analysis addresses both standard dual tires (295/75R22.5) along with the newer increasingly popular wide-base tire size 445/50R22.5.

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CARBON BLACK FOR RACING AND MOTORCYCLE TIRE TREADS. PERFORMANCE MODEL DEVELOPMENT

Rubber Chemistry and Technology ◽

10.5254/1.3601884 ◽

2011 ◽

Vol 84 (4) ◽

pp. 493-506

Author(s):

Irene S. Yurovska ◽

Michael D. Morris ◽

Theo Al

Keyword(s):

Carbon Black ◽

Critical Role ◽

Model Development ◽

Aggregate Size ◽

Rolling Resistance ◽

Performance Model ◽

Average Life ◽

Carbon Blacks ◽

Truck Tires ◽

And Performance

Abstract Racing tires and motorcycle tires present individual segments of the tire market. For instance, while the average life of car and truck tires is 50 000 miles, the average life of race tires is 100 miles. Because tires play a critical role in a race, technical demands to assure safety and performance are growing. Similarly, tires have a large influence on safety, handling/grip, and performance of the rapidly growing world fleet of motorcycles, due to the fact of only two wheels being in contact with the ground. Thus, the common feature of both market segments is that the typical tire compromise of wear, rolling resistance, and traction is strongly weighted toward traction. Most of the recent efforts of rubber scientists have been directed toward lowering rolling resistance of the tread compounds, which left a certain void in the science of compounding for racing and motorcycle treads. Particularly, the industrial assortment of polymers and fillers used for motorcycle treads is commonly different from that used for car or truck treads, but it is not known how the filler properties affect the hysteresis–stiffness compromise. The objective of this study is to evaluate the effects of the carbon black characteristics on the important properties of a typical racing and motorcycle tire tread compound. More than 50 individual carbon blacks were mixed in a SBR formulation. The acquired data were statistically analyzed, and a linear multiple regression model was developed to relate rubber properties (responses), such as static modulus, complex dynamic modulus, hysteresis, and viscosity to the key carbon black characteristics (variables) of surface area, structure, aggregate size distribution, and surface activity. Prediction profiles created from the model demonstrate rubber performance limits for the range of carbon blacks tested, and indicate the niches to provide required combinations of the rubber properties.

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Relationship between stringent customer environmental requirements and environmental performance in sustainable supply chain

2017 IEEE International Conference on Industrial Engineering and Engineering Management (IEEM) ◽

10.1109/ieem.2017.8289934 ◽

2017 ◽

Author(s):

M. R. H. Shumon ◽

S. Rahman ◽

K. Ahsan

Keyword(s):

Supply Chain ◽

Environmental Performance ◽

Sustainable Supply Chain ◽

Environmental Requirements

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Natural Rubber Compounds for Truck Tires

Rubber Chemistry and Technology ◽

10.5254/1.3536090 ◽

1985 ◽

Vol 58 (4) ◽

pp. 740-750 ◽

Cited By ~ 6

Author(s):

D. Barnard ◽

C. S. L. Baker ◽

I. R. Wallace

Keyword(s):

Stearic Acid ◽

Heat Generation ◽

Rolling Resistance ◽

Synthetic Compound ◽

Wear Performance ◽

Test Pieces ◽

Truck Tire ◽

Truck Tires ◽

Rubber Compounds ◽

Lower Severity

Abstract An 80 NR/20 BR truck tread compound containing a semi-EV cure system and modified with a 6.0 phr level of stearic acid has been shown to exhibit excellent resistance to reversion when compared to a similar compound containing a normal 2.0 phr level of stearic acid. Improvements in the retention of laboratory abrasion resistance, heat generation, and most physical properties have been identified on test pieces subjected to typical truck retread overcure conditions. In highway fleet testing trials of 1100 × 22.5 truck retreads fitted to both third and fourth drive axles of tipper trucks, the modified compound displayed a 42% improvement in treadwear performance over the normal compound in the lower severity third axle positions while performance in the higher severity fourth axle positions was inferior by 20%. In comparison to a 55 SBR/45 BR truck tread, both NR compounds displayed superior wear performance on the fourth axles while some further adjustments of the modified compound are required to match the synthetic compound on the third axles. The reversal of wear performances for all compounds between third and fourth axles is due to the different abrasion mechanisms encountered. Laboratory abrasion rankings do not correlate with wear performances of compounds on the fourth drive axle of trucks, but they do correlate with wear performances on third drive axles. Despite the reversion characteristics of the normal semi-EV compound, no significant adverse effect on treadwear performance was evident at the start of tire life. The low heat generation of the modified compound in laboratory tests is confirmed in actual tire testing. Advantages in rolling resistance characteristics are also evident for the modified compound. Current studies at MRPRA suggest that further modifications of cure system design, in combination with the optimization of NR/BR ratios and mixing methods, will potentially provide NR dominant truck tread compounds which will exhibit superior wear performance in both the higher and lower abrasion severities encountered in heavy-duty truck tire service conditions.

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Tire Rolling Resistance from Whole-Tire Hysteresis Ratio

Rubber Chemistry and Technology ◽

10.5254/1.3538623 ◽

1992 ◽

Vol 65 (2) ◽

pp. 444-452 ◽

Cited By ~ 9

Author(s):

P. S. Pillai ◽

G. S. Fielding-Russell

Keyword(s):

Rolling Resistance ◽

Simple Equation ◽

General Applicability ◽

Full Size ◽

Truck Tire ◽

Truck Tires ◽

Wide Range

Abstract A simple equation for tire rolling resistance in terms of whole-tire hysteresis ratio, tire load, and footprint dimensions has been developed from energetic considerations. The rolling resistances of a number of radial passenger and truck tires have been calculated using the equation, and the calculated values were successfully compared with the measured results. The general applicability of the equation was illustrated by predicting the rolling resistances of a wide range of tires—from an experimental HR78-8 minitire to a full size 11R24.5 truck tire.

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A novel evaluation on rolling resistance characteristics of truck tire through the simplified experimental modal analysis

Proceedings of the Institution of Mechanical Engineers Part D Journal of Automobile Engineering ◽

10.1177/0954407020920032 ◽

2020 ◽

Vol 234 (12) ◽

pp. 2771-2782

Author(s):

Chengwei Zhu ◽

Jingjing Yan ◽

Ye Zhuang ◽

Xueliang Gao ◽

Qiang Chen ◽

...

Keyword(s):

Polyvinylidene Fluoride ◽

Evaluation Method ◽

Single Point ◽

Rolling Resistance ◽

Damping Characteristics ◽

Truck Tire ◽

Truck Tires ◽

Half Power ◽

Resistance Coefficients ◽

Correlative Relationship

A novel evaluation method for the rolling resistance characteristics of truck tire is proposed, in which a simplified modal experiment is suggested through a single-point vibration sampling from the tire surface with a polyvinylidene fluoride (PVDF) piezoelectric film. Three truck tires are utilized in the modal experiments, and the half-power bandwidth method is employed to identify the damping characteristics of the three tires. The damping characteristics of the tires are ranked by their values. These values are compared with their corresponding rolling resistance coefficients to manifest their correlative relationship. The experimental results, which are obtained from the modal experiment and the rolling resistance test, indicate that the modal parameters and the half-power bandwidth of the tire are exactly correlated to the rolling resistance coefficients. Furthermore, the damping ratios of the tires are correlated well with the rolling resistance coefficients among the tires. Overall, the proposed evaluation method could effectively evaluate the rolling resistance characteristics of the tire, which enable it to be a simple and economical alternative over the conventional tire rolling resistance experiments.

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Tire Temperature and Rolling Resistance Prediction with Finite Element Analysis

Tire Science and Technology ◽

10.2346/1.2135974 ◽

1999 ◽

Vol 27 (1) ◽

pp. 2-21 ◽

Cited By ~ 70

Author(s):

T. G. Ebbott ◽

R. L. Hohman ◽

J.-P. Jeusette ◽

V. Kerchman

Keyword(s):

Finite Element ◽

Constitutive Modeling ◽

Rolling Resistance ◽

Transient Temperature ◽

Element Analysis ◽

Temperature Distributions ◽

Truck Tires ◽

Steady State Temperature ◽

Resistance Prediction ◽

Thermomechanical Method

Abstract A finite element-based method is demonstrated to predict tire rolling resistance and temperature distributions. Particular attention is given to the material properties and constitutive modeling as these have a significant effect on the predictions. A coupled thermomechanical method is described where both the stiffness and the loss properties are updated as a function of strain, temperature, and frequency. Results for rolling resistance and steady state temperature distribution are compared with experiments for passenger and radial medium truck tires. An extension of the method for transient temperature predictions is also demonstrated.

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MATERIALS DEVELOPMENT FOR LOWERING ROLLING RESISTANCE OF TIRES

Rubber Chemistry and Technology ◽

10.5254/rct.16.83805 ◽

2016 ◽

Vol 89 (1) ◽

pp. 79-116 ◽

Cited By ~ 21

Author(s):

Ping Zhang ◽

Michael Morris ◽

Dhaval Doshi

Keyword(s):

High Temperatures ◽

Fuel Economy ◽

Operating Cost ◽

Rolling Resistance ◽

Hysteresis Loss ◽

Market Demand ◽

Fuel Cost ◽

Heavy Duty ◽

Truck Tires ◽

Rubber Compounds

ABSTRACT Many countries are implementing regulatory programs to promote the use of transportation technologies that can reduce greenhouse gas emissions and enhance fuel economy of vehicles. These regulatory programs create a need for more durable and fuel-efficient tires. The increased cost of fuel for motor vehicles creates another driving force for improving the fuel economy of vehicles. Commercial vehicle operators recognize that fuel cost is a major driver of the total operating cost; therefore, they increasingly demand tires that are optimized for reducing the fuel cost of a trucking fleet. Rolling resistance of truck tires accounts for about one-third of the power required to move a heavy-duty truck and is the second most important contributor, after engine loss, to the total energy loss of heavy-duty trucks. Other than tire designs, rubber compound hysteresis contributes to the rolling resistance of tires, which affects vehicle fuel economy. There is a significant market demand, due to governmental regulations, concerns for the environment, and cost savings to the consumers, for developing tread compounds or tread compound systems that can reduce tire rolling resistance while maintaining the treadwear and durability of truck tires. This paper reviews materials technologies developed for reducing the hysteresis loss of rubber compounds at high temperatures, hence lowering the rolling resistance of tires. Compounding approaches that can be used to lower the hysteresis loss of rubber compounds and to reduce rolling resistance of tires also are discussed. Developments in elastomers and reinforcing materials, including nanoparticles, are highlighted, with focus on the benefits of those polymers and particles in reducing the hysteresis loss at high temperatures of rubber compounds.

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