Ignition by electrical discharges
Project 5 is focused on the experimental examination of ignition by electrical discharges with respect to safety assessment in hazardous areas. In the first period, two important types of electrical discharges – non-equilibrium plasmas due to streamer discharges and thermal plasmas – shall be examined.
The energy of an examined electrical discharge is always near the minimum ignition energy. Using optical emission spectroscopy, detailed information about the temporal evolution of atomic oxygen and rotational and vibrational temperatures of molecular nitrogen can be yielded. Time and spatially resolved laser-induced fluorescence measurements of OH radicals will be performed yielding four subsequent images during one single ignition event. Hence, detailed information about flame kernel growth and flame velocities can be derived. In the case of ignition by non-equilibrium plasmas detailed examination of atomic oxygen using two-photon absorption laser-induced fluorescence will be used to examine the temporal evolution of this radical in the ignition volume. All these experiments are necessary a) in the case of thermal plasmas to determine the thermal losses towards the electrodes and b) in the case of non-equilibrium plasmas to develop a kinetic scheme of the chemical processes by streamer discharges.
Along with numerical simulations of these processes useful information about the ignition process induced by electrical discharges will be yielded.
Scientists
| Project leader |  Dr.-Ing. Detlev Markus |
| Researcher |  Stefan Essmann |
Publication single view
Title: |
Experimental Investigation of the Ignition by Repetitive Streamer Discharges |
|---|---|
| Author(s): | , , , and |
| Year: | 2011 |
| Month: | June |
| Day: | 27 |
| Book title: | 42nd AIAA Plasmadynamics and Lasers Conference |
| Conference place: | Honolulu, Hawaii |
| Conference date: | 27. - 30. June 2011 |
| DOI: | 10.2514/6.2011-3451 |
| Tags: | AIAA 2011-3451 |
| Abstract: | A time-resolved study of the flame kernel growth after the ignition of different H2/air mixtures at atmospheric pressure is reported. For this purpose, hydroxyl radicals are measured by means of planar laser-induced fluorescence (OH-PLIF). The H2/air mixtures are ignited by repetitively pulsed streamer discharges which occur at atmospheric pressure within a rod/plane electrode configuration using alternating voltage amplitudes of up to 20 kV with a frequency of 740 kHz. The flame propagation is examined evaluating the flame front position from the signal intensities of the OH-PLIF. Numerical simulations of the ignition of H2/air mixtures are performed using well-known detailed chemistry and transport models based on a one-dimensional model. Numerical and experimental flame kernel growths are compared showing excellent agreement. The results will be used to achieve a better understanding of the molecular reactions in the non-equilibrium plasma of repetitive streamer discharges. |