EXP 1-1 Measurement Quantities and Techniques: Difference between revisions
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A multiline <math> Ar-Ion^{+}</math> laser produced a horizontally polarised light beam with 0.35 W output power. The green (514.5 nm) and blue (488 nm) wavelength components were extracted and used to provide two-component velocity measurements (in the Y and Z-axis) in the coincidence mode simultaneously with droplet sizing. Both the beams were split into a pair of parallel beams with a separation of 38 mm which were consequently expanded by a 1.98× beam expander and symmetrically intersected using transmitting optics. The frequency of one beam from each pair was shifted by 40 MHz. The intersected beams formed an elongated ellipsoidal measurement volume with the axes length of 0.123 × 0.123 × 1.63 mm. The measurement volume length was truncated by a 0.1-mm wide spatial filter. The positioning of the receiving optics at 48° from the forward direction was used to collect the light scattered from droplets dominated by the first order of refraction and to minimise reflections from windows. Both transmitting and receiving optics used lenses with 500 mm focal lengths. The principle of phase Doppler anemometry, data processing, measurement precision and uncertainties and other features are explained in [59]. | A multiline <math> Ar-Ion^{+}</math> laser produced a horizontally polarised light beam with 0.35 W output power. The green (514.5 nm) and blue (488 nm) wavelength components were extracted and used to provide two-component velocity measurements (in the Y and Z-axis) in the coincidence mode simultaneously with droplet sizing. Both the beams were split into a pair of parallel beams with a separation of 38 mm which were consequently expanded by a 1.98× beam expander and symmetrically intersected using transmitting optics. The frequency of one beam from each pair was shifted by 40 MHz. The intersected beams formed an elongated ellipsoidal measurement volume with the axes length of 0.123 × 0.123 × 1.63 mm. The measurement volume length was truncated by a 0.1-mm wide spatial filter. The positioning of the receiving optics at 48° from the forward direction was used to collect the light scattered from droplets dominated by the first order of refraction and to minimise reflections from windows. Both transmitting and receiving optics used lenses with 500 mm focal lengths. The principle of phase Doppler anemometry, data processing, measurement precision and uncertainties and other features are explained in [59]. | ||
Three planes in the spray were probed at axial positions Z = 10, 15 and 20 mm from the nozzle exit. For each plane, seven lines perpendicular to the flow direction and one line parallel with the flow direction in the atomiser axis were measured as seen in '''Figure 10'''. At each point, either 50 000 droplet samples were acquired or a 10-second acquisition duration was achieved. The Dantec BSA software 5.2 was used to control the measurement. The PDA configuration is described in '''Table 3'''. Each sample contains information on diameter and velocity components in the Y and Z-axis as detailed in the section ''Measurement data/results''. | Three planes in the spray were probed at axial positions Z = 10, 15 and 20 mm from the nozzle exit. For each plane, seven lines perpendicular to the flow direction and one line parallel with the flow direction in the atomiser axis were measured as seen in '''Figure 10'''. At each point, either 50 000 droplet samples were acquired or a 10-second acquisition duration was achieved. The Dantec BSA software 5.2 was used to control the measurement. The PDA configuration is described in '''Table 3'''. Each sample contains information on diameter and velocity components in the Y and Z-axis as detailed in the section ''Measurement data/results''. | ||
[[File:PDAsetup.png|center|300px|frame|Figure 9: PDA setup]] | |||
[[File:Measurement_scheme.png|center|300px|frame|Figure 10: Measurement scheme with the arrangement of the measurement points]] | |||
{| class="wikitable" style="text-align:center;" style="margin: auto;" | |||
|- style="font-weight:bold;" | |||
! <br />Parameter | |||
! colspan="2" | <br />Value | |||
|- style="background-color:#F2F2F2;" | |||
| <br />Laser power output | |||
| colspan="2" | <br />0.35 W | |||
|- | |||
| <br />Scattering angle | |||
| colspan="2" | <br />48° | |||
|- style="background-color:#F2F2F2;" | |||
| <br />Receiver mask | |||
| colspan="2" | <br />B | |||
|- | |||
| <br />Receiver spatial filter | |||
| colspan="2" | <br />0.1 mm | |||
|- style="background-color:#F2F2F2;" | |||
| <br />The focal length of transmitting/receiving optics | |||
| colspan="2" | <br />500/500 mm | |||
|- | |||
| <br />Wavelength | |||
| <br />488 nm | |||
| <br />514.5 nm | |||
|- style="font-weight:bold; background-color:#F2F2F2;" | |||
| style="font-weight:normal;" | <br />Velocity component | |||
| <br />Axial | |||
| <br />Radial | |||
|- | |||
| <br />Velocity centre | |||
| <br />19 m/s | |||
| <br />0 m/s | |||
|- style="background-color:#F2F2F2;" | |||
| <br />Velocity span | |||
| <br />51 m/s | |||
| <br />73 m/s | |||
|- | |||
| <br />Sensitivity | |||
| <br />800 V | |||
| <br />1050 V | |||
|- style="background-color:#F2F2F2;" | |||
| <br />SNR | |||
| <br />0 dB | |||
| <br />0 dB | |||
|- | |||
| <br />Signal gain | |||
| <br />8 dB | |||
| <br />10 dB | |||
|- style="background-color:#F2F2F2;" | |||
| <br />Level validation ratio | |||
| <br />8 | |||
| <br />2 | |||
|} | |||
== High-speed visualisation == | |||
An HSC FASTCAM SA-Z type 2100K-M-16GB (Photron, Japan) was used to capture the instantaneous images of the spray under cross-flow. Led light model HPL3-36DD18B (Lightspeed Technologies, USA) provided spray illumination with a light pulse duration of 400 ns. The camera was equipped with a long-distance microscope 12 X Zoom lens (NAVITAR, New York, USA) composed of a 2X F -mount adapter (type 1 –62922), a 12 mm F.F zoom lens (type 1 –50486) together with 0.25 X lens (type 1 –50011). | |||
Two different high-speed measurements were carried out. First, the visualisation of the spray trajectory was performed with the aim of recording the maximum possible area with sufficient pixel size for resolving important flow features. The second liquid sheet was visualised in detail to extract the sheet break-up length and surface wave structure. | |||
The camera recorded for each measurement and flow regime a sequence of 4000 instantaneous images at a frame rate of 60,000 frames per second (fps) with an image resolution of 512 × 512 pixels (width × height) and at a shutter speed of 1 µs. The image area was 23.58 × 23.58 <math>mm^2</math> and 11.44 × 11.44 <math>mm^2</math> for the first and second measurement, respectively. The depth of field was approximately 6 and 13 mm respectively. | |||
The spatial resolution is hence in the first case 46 μm/pix × 46 μm/pix, allowing the detection of large liquid structures to determine the spray trajectory in cross-flow. In the second case, it is 22.3 μm/pix × 22.3 µm/pix for the precise extraction of the liquid sheet break-up position. The camera axis was aligned perpendicularly to the flow and the main atomiser axis with backlit illumination, see '''Figure 11'''. | |||
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Revision as of 16:07, 14 May 2023
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Measurement quantities and techniques
Measurement setup of PDA
The size and velocity of droplets in the spray were determined using a two-component fibre-based PDA measurement system (Dantec Dynamics A/S Skovlunde, Denmark). The arrangement of the measurement setup is shown in Figure 9. A multiline laser produced a horizontally polarised light beam with 0.35 W output power. The green (514.5 nm) and blue (488 nm) wavelength components were extracted and used to provide two-component velocity measurements (in the Y and Z-axis) in the coincidence mode simultaneously with droplet sizing. Both the beams were split into a pair of parallel beams with a separation of 38 mm which were consequently expanded by a 1.98× beam expander and symmetrically intersected using transmitting optics. The frequency of one beam from each pair was shifted by 40 MHz. The intersected beams formed an elongated ellipsoidal measurement volume with the axes length of 0.123 × 0.123 × 1.63 mm. The measurement volume length was truncated by a 0.1-mm wide spatial filter. The positioning of the receiving optics at 48° from the forward direction was used to collect the light scattered from droplets dominated by the first order of refraction and to minimise reflections from windows. Both transmitting and receiving optics used lenses with 500 mm focal lengths. The principle of phase Doppler anemometry, data processing, measurement precision and uncertainties and other features are explained in [59]. Three planes in the spray were probed at axial positions Z = 10, 15 and 20 mm from the nozzle exit. For each plane, seven lines perpendicular to the flow direction and one line parallel with the flow direction in the atomiser axis were measured as seen in Figure 10. At each point, either 50 000 droplet samples were acquired or a 10-second acquisition duration was achieved. The Dantec BSA software 5.2 was used to control the measurement. The PDA configuration is described in Table 3. Each sample contains information on diameter and velocity components in the Y and Z-axis as detailed in the section Measurement data/results.
Parameter |
Value | |
---|---|---|
Laser power output |
0.35 W | |
Scattering angle |
48° | |
Receiver mask |
B | |
Receiver spatial filter |
0.1 mm | |
The focal length of transmitting/receiving optics |
500/500 mm | |
Wavelength |
488 nm |
514.5 nm |
Velocity component |
Axial |
Radial |
Velocity centre |
19 m/s |
0 m/s |
Velocity span |
51 m/s |
73 m/s |
Sensitivity |
800 V |
1050 V |
SNR |
0 dB |
0 dB |
Signal gain |
8 dB |
10 dB |
Level validation ratio |
8 |
2 |
High-speed visualisation
An HSC FASTCAM SA-Z type 2100K-M-16GB (Photron, Japan) was used to capture the instantaneous images of the spray under cross-flow. Led light model HPL3-36DD18B (Lightspeed Technologies, USA) provided spray illumination with a light pulse duration of 400 ns. The camera was equipped with a long-distance microscope 12 X Zoom lens (NAVITAR, New York, USA) composed of a 2X F -mount adapter (type 1 –62922), a 12 mm F.F zoom lens (type 1 –50486) together with 0.25 X lens (type 1 –50011). Two different high-speed measurements were carried out. First, the visualisation of the spray trajectory was performed with the aim of recording the maximum possible area with sufficient pixel size for resolving important flow features. The second liquid sheet was visualised in detail to extract the sheet break-up length and surface wave structure. The camera recorded for each measurement and flow regime a sequence of 4000 instantaneous images at a frame rate of 60,000 frames per second (fps) with an image resolution of 512 × 512 pixels (width × height) and at a shutter speed of 1 µs. The image area was 23.58 × 23.58 and 11.44 × 11.44 for the first and second measurement, respectively. The depth of field was approximately 6 and 13 mm respectively. The spatial resolution is hence in the first case 46 μm/pix × 46 μm/pix, allowing the detection of large liquid structures to determine the spray trajectory in cross-flow. In the second case, it is 22.3 μm/pix × 22.3 µm/pix for the precise extraction of the liquid sheet break-up position. The camera axis was aligned perpendicularly to the flow and the main atomiser axis with backlit illumination, see Figure 11.
Contributed by: Ondrej Cejpek, Milan Maly, Ondrej Hajek, Jan Jedelsky — Brno University of Technology
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