Your search keyword '"Tobias Michler"' showing total 2 results

1. Measurement of temporal and spatial resolved rotational temperature in ignition sparks at atmospheric pressure

Author

Tobias Michler, Thomas Koch, and Olaf Toedter

Subjects

Spark Temperature, Materials science, Ignition coil, Glow phase, 01 natural sciences, law.invention, Electric arc, 03 medical and health sciences, law, Breakdown, Spark phases, 0103 physical sciences, 010306 general physics, Spark plug, Engineering & allied operations, 030304 developmental biology, General Environmental Science, 0303 health sciences, Glow discharge, Atmospheric pressure, General Engineering, Rotational temperature, Ignition, Ignition system, Dwell time, General Earth and Planetary Sciences, ddc:620, Atomic physics, Arc phase

Abstract

In this work, the temporal and spatial rotational temperature, as an indicator of spark temperature in the gas, of an ignition spark at ambient pressure is determined. With optical emission spectroscopy, the rotational bands of the nitrogen C3Πu → B3Πg transition at a wavelength of 337 nm are for determination. In addition, the electrical values of the current and the voltage are measured with a digital storage oscilloscope. All measurements are performed with a common nickel spark plug and a commercial 90 mJ ignition coil. The dwell time of the coil is varied in four steps from 100 to 25% and the influence on the rotational temperature is measured. The results are split into the three spark phases: breakdown, arc discharge, and glow discharge. The results show a cold breakdown, which is independent from the dwell time. On average, arc discharge is the hottest discharge phase, while the glow discharge has a medium rotational temperature.

Published

2020

2. Gasoline from the bioliq® process: Production, characterization and performance

Author

Thomas Koch, Thomas Otto, Jörg Sauer, Ulrich Arnold, Benjamin Niethammer, Olaf Toedter, Tobias Michler, Nicolas Wippermann, and Stephan Pitter

Subjects

020209 energy, General Chemical Engineering, Energy Engineering and Power Technology, chemistry.chemical_element, Fraction (chemistry), 02 engineering and technology, medicine.disease_cause, chemistry.chemical_compound, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, medicine, Dimethyl ether, 0204 chemical engineering, Gasoline, Engineering & allied operations, chemistry.chemical_classification, Waste management, Soot, Fuel Technology, Hydrocarbon, chemistry, Environmental science, ddc:620, Pyrolysis, Carbon, Syngas

Abstract

Within the so-called bioliq® process, renewable carbon resources, especially agricultural residues, are converted to gasoline. The process chain comprises pyrolysis of the feedstocks, gasification to synthesis gas, gas cleaning and conversion of synthesis gas to dimethyl ether (DME) followed by conversion of DME to hydrocarbons. Construction of all process units has been completed now and the entire plant has been successfully operated in several campaigns. Thus, hundreds of liters of a new alternative gasoline are available now, which allow for an extensive testing. The basic characteristics of the resulting bioliq®/100 fuel are described. It is rich in aromatics and a blend consisting of 90 Vol.−% of conventional RON95 E5 fuel and 10 Vol.−% of bioliq®/100, designated as bioliq®/10, has been produced which meets the DIN EN 228 standard. Initial measurements on a single cylinder research engine have been carried out focusing on efficiency and emissions. A comparison of bioliq®/10 with neat RON95 E5 revealed an improved knocking behavior of bioliq®/10 even by a small fraction of regenerative bioliq® fuel. Particle as well as hydrocarbon emissions from bioliq®/10 are significantly higher than in the case of RON95 E5. Increased particle emissions are attributed to the higher content of aromatics. Soot reactivity has been investigated and soot from bioliq®/10 exhibits higher reactivity than soot from RON95 E5.

Published

2020