Using a Dynamometer Along With Road Tests to Measure Vehicle Rolling and Wind Noise

2008 ◽  
Author(s):  
Richard E. Wentzel ◽  
Allan Aubert
Keyword(s):  
Operating Conditions ◽  
Interior Noise ◽  
Wind Tunnels ◽  
Sport Utility Vehicle ◽  
Wind Noise ◽  
Pickup Truck ◽  
The Road ◽  
Noise Data ◽  
Rolling Noise ◽  
Utility Vehicle

The consumer today places greater demands upon the vehicle acoustical engineer than in the past. Product quality has always been associated with a quiet ride. Automotive engineers recognize that the predominant sources of vehicle interior noise are wind, tire-road or rolling noise, and the powertrain. This paper suggests a test protocol for measuring wind and rolling noise using a chassis rolls dynamometer and road tests. Automotive engineers are frequently confronted by customer complaints concerning wind noise. Usually, engineers resort to using wind tunnels to address these concerns and to conduct diagnostic studies to remedy wind noise problems. Unfortunately, wind tunnels are expensive to rent and difficult to schedule. As an alternative, the engineer can learn a great deal about the wind noise of a vehicle by using a chassis rolls dynamometer along with road tests [1,2]. If the chassis rolls surface texture closely matches that of the road surface, the tire-road or rolling noise signal in both situations can be assumed to be equivalent. The powertrain noise source can be minimized by shifting the vehicle into neutral and coasting. Wind noise is a source for the road measurements, but not for the chassis rolls. Hence, the wind noise can be calculated by measuring the cab interior noise for both operating conditions, and subtracting the rolling noise measured on the chassis rolls. The two vehicles tested in this study included a pickup truck and a sport utility vehicle. The acoustical data revealed significantly different rolling and wind noise characteristics. The pickup truck had significantly louder rolling noise, and the wind noise was dominated by low frequency sound. The sport utility vehicle was much quieter overall and was significantly quieter for rolling noise than the pickup. The wind noise of the sport utility vehicle also was dominated by high frequency components. Both vehicles showed that rolling and wind noise trends increase linearly with speed. However, the slope of wind noise data for the sport utility vehicle was much steeper than the pickup, which suggested that it was more sensitive to wind noise as speed increased. Exterior noise data from both vehicles showed that the tire-road signal from the road differed significantly from that of the chassis rolls dynamometer. Rolling & wind noises will become even more critical as the motor vehicle industry adopts hybrid electric and, in the future electric fuel cell vehicles, because powertrain noise sources in the vehicle will likely be reduced. The procedure suggested here provides an inexpensive simple approach to assessing rolling and wind noise in the vehicle.

Assessment of NCHRP Report 350 Test Vehicles

2002 ◽  
Vol 1797 (1) ◽  
pp. 33-37
Author(s):  
King K. Mak ◽  
Roger P. Bligh
Keyword(s):  
Potential Problem ◽  
Sport Utility Vehicle ◽  
Passenger Cars ◽  
Test Vehicle ◽  
Passenger Car ◽  
Pickup Truck ◽  
Current Test ◽  
Entire Vehicle ◽  
The Matrix ◽  
Utility Vehicle

The appropriateness of test vehicles specified in NCHRP Report 350 was assessed, including ( a) whether the 2000-kg, three-quarter-ton pickup truck should continue to be used as a test vehicle, and if not, what replacement vehicle would be appropriate; ( b) whether the 820-kg passenger car should continue to be used as a test vehicle, and if not, what replacement vehicle would be appropriate; and ( c) whether another test vehicle should be added to the matrix—for example, an intermediate-sized passenger car. From the analysis, the following conclusions and recommendations were drawn: ( a) The three-quarter-ton pickup truck appears to be a good surrogate for the light truck subclasses. The recommendation is to keep the 2000-kg, three-quarter-ton pickup truck as one of the design test vehicles in the update of the guidelines for NCHRP Report 350. ( b) A potential problem is the availability of three-quarter-ton pickup trucks with standard cabs. An alternative design test vehicle may be an intermediate-sized sport utility vehicle, ( c) The availability of the 820-kg passenger car design test vehicle will be a problem within the next few years. The recommendation is to keep the current test vehicle as long as it is still readily available, or until the NCHRP Report 350 guidelines are updated, and to increase the curb weight to a level consistent with the curb weights of the two smallest passenger cars with reasonably high sales volume. ( d) The addition of a third design vehicle—for example, a 1500-kg intermediate-sized passenger car—to ensure that a roadside feature performs satisfactorily across the entire vehicle spectrum is highly desirable but cost-prohibitive. The addition of an intermediate-sized design test vehicle is therefore not recommended except in situations in which there is a perceived concern that the device may not function properly when impacted by an intermediate-sized vehicle.

scholarly journals Understanding the contribution of groove resonance to tire-road noise on different surfaces under various operating conditions

Acta Acustica ◽  
2020 ◽  
Vol 4 (2) ◽  
pp. 6
Author(s):  
Julien Pinay ◽  
Yoshinori Saito ◽  
Christian Mignot ◽  
Frank Gauterin
Keyword(s):  
Development Process ◽  
Test Bench ◽  
Operating Conditions ◽  
Acoustic Measurements ◽  
Resonance Contribution ◽  
Road Noise ◽  
Spectral Content ◽  
The Road ◽  
Driving Speed ◽  
Rolling Noise

Reducing tire-road noise is now becoming more and more important during the tire development process. Tread profile randomization is used to avoid tonal components and reduce groove resonance noise. To better understand the groove resonance contribution to tire-road noise, we performed acoustic measurements on a test bench with two serial tires. We filled the grooves with acoustic foam to highlight the groove resonance’s contribution. We then varied the road surface, the tire load and the driving speed. In the end, we used a multiple linear regression to quantify the interaction between the varying parameters and the groove resonance noise. We show that groove resonance contributes an average of 1.7 dBA to the tire rolling noise of passenger car tires. Groove resonance noise also increases with the driving speed. While the tread pattern and the tire load are responsible for the spectral content of the groove resonance noise, the orientation of the road surface’s texture mainly influences the noise level of the groove resonance. The tire manufacturers should carefully consider these findings when developing noise-optimized patterns. This is especially true for tire approval tests, which take place on tracks and usually have a relatively low texture level that is oriented negatively.

Determination of Events Leading to Sport Utility Vehicle Rollover

2005 ◽  
Vol 1908 (1) ◽  
pp. 180-186 ◽  
Author(s):  
Daniel Blower ◽  
John Woodrooffe ◽  
Paul Green ◽  
Anne Matteson ◽  
Michael Shrank
Keyword(s):  
Surface Condition ◽  
Stability Control ◽  
Loss Of Control ◽  
Sport Utility Vehicle ◽  
Sampling System ◽  
The Road ◽  
Crash Avoidance ◽  
The Stability ◽  
Transportation Research ◽  
Utility Vehicle

To determine the major event pathways that result in sport utility vehicle (SUV) rollover, researchers at the University of Michigan Transportation Research Institute examined SUV rollover cases selected from the National Automotive Sampling System crashworthiness data system files for 1999 to 2001. Selected SUVs included the Ford Explorer, Jeep Cherokee, Chevrolet Blazer, Toyota 4-Runner, and GMC Jimmy for model years 1989 to 2001. Researchers coded up to six pre-rollover events, along with the stability of the vehicle (tracking or skidding) after each event. In addition, crash avoidance and recovery maneuvers were recorded, along with the rollover initiation type, location of rollover initiation, direction of roll, number of quarter turns of roll, location of roll, and surface condition at rollover initiation. Approximately 34% of SUV rollovers began with a loss of control caused by tire saturation, and about 75% of the loss-of-control cases were on icy, wet, or snowy roads. Of the SUVs that ran off the road as the first event, 47% returned to the road before rolling over, and of these, 76% were tracking (presumed under control) before initial road departure. Between 40% and 49% of SUV rollover crashes experienced yaw instability while still on the roadway before roll. These rollovers may be addressed by electronic stability control devices if such devices can increase the control limits of the vehicle.

Investigations of Road Wear Caused by Studded Tires

2014 ◽  
Vol 42 (1) ◽  
pp. 2-15
Author(s):  
Johannes Gültlinger ◽  
Frank Gauterin ◽  
Christian Brandau ◽  
Jan Schlittenhard ◽  
Burkhard Wies
Keyword(s):  
Traffic Safety ◽  
Test Bench ◽  
Operating Conditions ◽  
Test Method ◽  
Analytical Models ◽  
The Road ◽  
Driving Speed ◽  
Major Factors ◽  
Tire Friction ◽  
Variable Operating Conditions

ABSTRACT The use of studded tires has been a subject of controversy from the time they came into market. While studded tires contribute to traffic safety under severe winter conditions by increasing tire friction on icy roads, they also cause damage to the road surface when running on bare roads. Consequently, one of the main challenges in studded tire development is to reduce road wear while still ensuring a good grip on ice. Therefore, a research project was initiated to gain understanding about the mechanisms and influencing parameters involved in road wear by studded tires. A test method using the institute's internal drum test bench was developed. Furthermore, mechanisms causing road wear by studded tires were derived from basic analytical models. These mechanisms were used to identify the main parameters influencing road wear by studded tires. Using experimental results obtained with the test method developed, the expected influences were verified. Vehicle driving speed and stud mass were found to be major factors influencing road wear. This can be explained by the stud impact as a dominant mechanism. By means of the test method presented, quantified and comparable data for road wear caused by studded tires under controllable conditions can be obtained. The mechanisms allow predicting the influence of tire construction and variable operating conditions on road wear.

Experimental Evaluation of Turbo-Matching Appropriateness of B60J67, B60J68, A58N70 and A58N72 Turbo-Chargers for a Commercial Vehicle Engine

2018 ◽  
Vol 6 (11) ◽  
pp. 71
Author(s):  
Badal Dev Roy ◽  
R. Saravanan
Keyword(s):  
Internal Combustion Engines ◽  
Perfect Match ◽  
Engine Performance ◽  
Operating Conditions ◽  
Data Logger ◽  
Negative Effects ◽  
Road Test ◽  
The Road ◽  
A Charge ◽  
All Speeds

The Turbocharger is a charge booster for internal combustion engines to ensure best engine performance at all speeds and road conditions especially at the higher load.  Random selection of turbocharger may lead to negative effects like surge and choke in the breathing of the engine. Appropriate selection or match of the turbocharger (Turbomatching) is a tedious task and expensive. But perfect match gives many distinguished advantages and it is a one time task per the engine kind. This study focuses to match the turbocharger to desired engine by simulation and on road test. The objective of work is to find the appropriateness of matching of turbochargers with trim 67 (B60J67), trim 68 (B60J68),  trim 70 (A58N70) and trim 72 (A58N72) for the TATA 497 TCIC -BS III engine. In the road-test (data-logger method) the road routes like highway and slope up were considered for evaluation. The operating conditions with respect various speeds, routes and simulated outputs were compared with the help of compressor map.

Field measurements of the harvestable power potentiality of an off-road sport-utility vehicle

Measurement ◽  
2021 ◽  
Vol 179 ◽  
pp. 109381
Author(s):  
Mohamed A.A. Abdelkareem ◽  
Lin Xu ◽  
Xingjian Jing ◽  
Abdelrahman B.M. Eldaly ◽  
Junyi Zou ◽  
...  
Keyword(s):  
Field Measurements ◽  
Sport Utility Vehicle ◽  
Utility Vehicle

Hysteresis loss of ultra-large off-the-road tire rubber compounds based on operating conditions at mine sites

2021 ◽  
pp. 095440702110155
Author(s):  
Shaosen Ma ◽  
Guangping Huang ◽  
Khaled Obaia ◽  
Soon Won Moon ◽  
Wei Victor Liu
Keyword(s):  
Large Strain ◽  
Tensile Tests ◽  
Operating Conditions ◽  
Hysteresis Loss ◽  
Strain Rates ◽  
Test Results ◽  
Tire Rubber ◽  
The Road ◽  
Rubber Compounds ◽  
Mine Sites

The objective of this study is to investigate the hysteresis loss of ultra-large off-the-road (OTR) tire rubber compounds based on typical operating conditions at mine sites. Cyclic tensile tests were conducted on tread and sidewall compounds at six strain levels ranging from 10% to 100%, eight strain rates from 10% to 500% s−1 and 14 rubber temperatures from −30°C to 100°C. The test results showed that a large strain level (e.g. 100%) increased the hysteresis loss of tire rubber compounds considerably. Hysteresis loss of tire rubber compounds increased with a rise of strain rates, and the increasing rates became greater at large strain levels (e.g. 100%). Moreover, a rise of rubber temperatures caused a decrease in hysteresis loss; however, the decrease became less significant when the rubber temperatures were above 10°C. Compared with tread compounds, sidewall compounds showed greater hysteresis loss values and more rapid increases in hysteresis loss with the rising strain rate.

A Design Concept for an Aluminum Sport Utility Vehicle Frame

2003 ◽  
Author(s):  
Michael W. Danyo ◽  
Christopher S. Young ◽  
Henry J. Cornille ◽  
Joseph Porcari
Keyword(s):  
Design Concept ◽  
Sport Utility Vehicle ◽  
Utility Vehicle
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