Tomographic imaging using multi-simultaneous measurements (TIMes) for flame emission reconstructions

The method of tomographic imaging using multi-simultaneous measurements (TIMes) for flame emission reconstructions is presented. Measurements of the peak natural CH* chemiluminescence in the flame and luminescence from different vaporised alkali metal salts that were seeded in a multi-annulus burner were used. An array of 29 CCD cameras around the Cambridge-Sandia burner was deployed, with 3 sets of cameras each measuring a different colour channel using bandpass optical filters. The three-dimensional instantaneous and time-averaged fields of the individual measured channels were reconstructed and superimposed for two new operating conditions, with differing cold flow Reynolds numbers. The contour of the reconstructed flame front followed the interface between the burnt side of the flame, where the alkali salt luminescence appears, and the cold gas region. The increased mixing between different reconstructed channels in the downstream direction that is promoted by the higher levels of turbulence in the larger Reynolds number case was clearly demonstrated. The TIMes method enabled combustion zones originating from different streams and the flame front to be distinguished and their overlap regions to be identified, in the entire volume. (c) 2020 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

Automated summary

The method of tomographic imaging using multi-simultaneous measurements (TIMes) for flame emission reconstructions was presented in this study. Measurements of peak natural CH* chemiluminescence and luminescence from different vaporized alkali metal salts in the flame were conducted. An array of 29 CCD cameras was deployed around the burner, with each set measuring a different color channel. The study demonstrated that the mixing between different reconstructed channels in the downstream direction is influenced by the Reynolds number.