Residual Stress in Automotive Powertrains: Methods and Analyses

Sediako, D.; Stroh, Joshua; Kianfar, Sina

doi:10.4028/www.scientific.net/msf.1016.1291

Cited by 5 publications

(2 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In most cases, important measured variables such as strain and temperature are measured with the help of resistive sensors. Metallic strain gauges are used in the automotive industry to measure strain as well as pressure condition of castings and engine blocks [1]. In the energy sector, temperature and strain sensors are used to quantitatively evaluate the structural performance of buried pipelines considering longitudinal bending loads and axial thermal stresses [2].…”

Section: Introductionmentioning

confidence: 99%

Advancements in Monitoring of Tribological Stress in Bearings Using Thin-Film Strain Gauges

Konopka,

Steppeler,

Ottermann

et al. 2023

10th ECCOMAS Thematic Conference on Smart Structures and Materials

View full text Add to dashboard Cite

The world's electrical energy demand is rising permanently and, at the same time, resources must be used economically and responsibly. An important part of the energy turnaround are wind mills, where conventional machine elements such as gears or rolling bearings find application. These parts have optimization potential in terms of service life and reliability. To advance this potential, sensor integration for intelligent system monitoring combined with a compact electronic solution has to be realized. In contrast to conventional condition monitoring systems (CMS), this article addresses thin-film sensors that will be applied inside the bearing system directly inside or close to the tribological contact enabling maximum information about the system's condition. For this purpose, thin-film strain gauges are directly deposited onto small steel bearing washers of a cylindrical roller thrust bearing system (CRTB) by photolithography and sputtering processes. The layer stack includes an aluminum oxide insulation layer, the sensor layer and an aluminum oxide wear protection coating. The sensor layer consists of an array of three differently aligned meander-shaped constantan strain gauges. Therefore, bearing washers with the sensors are tested on a pin-onplate tribometer under defined load conditions. The influence of normal force as well as velocity on the thin-film sensors could be detected in this study. During the tests, under Hertzian pressure up to 1 GPa and a constant sliding velocity of 8 mm/s, a maximum nominal resistance change ΔR/R 0 of up to -0.13 ‰ was measured. Changing the velocity from 1 mm/s to 8 mm/s resulted in maximum ΔR/R 0 values of -0.17 ‰. This enables the determination of the correlation between sensor signals and tribological stresses. Though Hertzian pressures of 950 MPa were applied, no sensor failure was observed during the experiments proving the functionality of the sensor layer system.

show abstract

Section: Introductionmentioning

confidence: 99%

Advancements in Monitoring of Tribological Stress in Bearings Using Thin-Film Strain Gauges

Konopka,

Steppeler,

Ottermann

et al. 2023

10th ECCOMAS Thematic Conference on Smart Structures and Materials

View full text Add to dashboard Cite

show abstract

“…Important measurement variables are strain and temperature, which are usually measured using resistive sensors. In the automotive sector, for example, metallic strain gauges are used to measure the strain and compression condition of cast parts and engine blocks [1]. In the energy sector, strain gauges are used in 3D-woven composite spar caps for structural health monitoring (SHM) of wind-turbine blades and a reduction in measurement costs [2].…”

Section: Introductionmentioning

confidence: 99%

Degeneration Effects of Thin-Film Sensors after Critical Load Conditions of Machine Components

et al. 2022

View full text Add to dashboard Cite

In the context of intelligent components in industrial applications in the automotive, energy or construction sector, sensor monitoring is crucial for security issues and to avoid long and costly downtimes. This article discusses component-inherent thin-film sensors for this purpose, which, in contrast to conventional sensor technology, can be applied inseparably onto the component’s surface via sputtering, so that a maximum of information about the component’s condition can be generated, especially regarding deformation. This article examines whether the sensors can continue to generate reliable measurement data even after critical component loads have been applied. This extends their field of use concerning plastic deformation behavior. Therefore, any change in sensor properties is necessary for ongoing elastic strain measurements. These novel fundamentals are established for thin-film constantan strain gauges and platinum temperature sensors on steel substrates. In general, a k-factor decrease and an increase in the temperature coefficient of resistance with increasing plastic deformation could be observed until a sensor failure above 0.5 % plastic deformation (constantan) occurred (1.3 % for platinum). Knowing these values makes it possible to continue measuring elastic strains after critical load conditions on a machine component in terms of plastic deformation. Additionally, a method of sensor-data fusion for the clear determination of plastic deformation and temperature change is presented.

show abstract

An Investigation of the Microstructure and Oil Retention of Electrolyte Jet Plasma Oxidation (EJPO) Coating

Bahramian

Kianfar

Stroh

et al. 2022

The Minerals, Metals &Amp; Materials Series

View full text Add to dashboard Cite

Residual Stress in Automotive Powertrains: Methods and Analyses

Cited by 5 publications

References 22 publications

Advancements in Monitoring of Tribological Stress in Bearings Using Thin-Film Strain Gauges

Advancements in Monitoring of Tribological Stress in Bearings Using Thin-Film Strain Gauges

Degeneration Effects of Thin-Film Sensors after Critical Load Conditions of Machine Components

An Investigation of the Microstructure and Oil Retention of Electrolyte Jet Plasma Oxidation (EJPO) Coating

Contact Info

Product

Resources

About