Abstract
In high-velocity open channel flows, the measurements of air–water flow properties are complicated by the strong interactions between the flow turbulence and the entrained air. In the present study, an advanced signal processing of traditional single- and dual-tip conductivity probe signals is developed to provide further details on the air–water turbulent level, time and length scales. The technique is applied to turbulent open channel flows on a stepped chute conducted in a large-size facility with flow Reynolds numbers ranging from 3.8E+5 to 7.1E+5. The air water flow properties presented some basic characteristics that were qualitatively and quantitatively similar to previous skimming flow studies. Some self-similar relationships were observed systematically at both macroscopic and microscopic levels. These included the distributions of void fraction, bubble count rate, interfacial velocity and turbulence level at a macroscopic scale, and the auto- and cross-correlation functions at the microscopic level. New correlation analyses yielded a characterisation of the large eddies advecting the bubbles. Basic results included the integral turbulent length and time scales. The turbulent length scales characterised some measure of the size of large vortical structures advecting air bubbles in the skimming flows, and the data were closely related to the characteristic air–water depth Y 90. In the spray region, present results highlighted the existence of an upper spray region for C > 0.95–0.97 in which the distributions of droplet chord sizes and integral advection scales presented some marked differences with the rest of the flow.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
In high-velocity open channel flows, the strong interactions between the turbulent waters and the atmosphere lead often to some air bubble entrainment. The entrained air is advected within the bulk of the flow and the air–water mixture has a whitish appearance (Fig. 1a). In civil engineering applications, the flow velocity exceeds typically 5–10 m/s, and the flow Reynolds number ranges from 1E+7 to over 1E+9 in large dam spillways. The void fraction ranges from 100% above the “free-surface” to some small, often non-zero value close to the invert (e.g. Cain and Wood 1981b). These high-velocity, highly-aerated flows cannot be studied analytically nor numerically because of the large number of relevant equations and parameters. Present knowledge relies upon physical modelling and experimental measurements. Accurate measurement systems for air–water flow measurements include intrusive phase-detection probes, hot-film probes, and LDA/PDA systems. Authoritative reviews include Jones and Delhaye (1976), Cain and Wood (1981a), Chanson (1997a, 2002) and Chang et al. (2003). The processing of these measurement techniques yield basically the void fraction, bubble count rate, interfacial velocity and turbulence intensity. Further information requires more advanced instrumentation: e.g., 4- or 5-sensor probes (Kim et al. 2000; Euh et al. 2006).
In the present study, it is shown that an advanced signal processing of traditional single- and dual-tip conductivity probes may provide further information on the air–water turbulent time and length scales. The technique was applied to turbulent open channel flows on a stepped chute. The measurements were conducted in a large-size facility (θ = 22°, h = 0.1 m) in which detailed air–water flow properties were recorded systematically for several flow rates including turbulence levels and turbulent time and length scales.
2 Experimental apparatus and procedures
2.1 Experimental flume
New experiments were performed a 3.2 m long 1 m wide flume with an average bed slope S o ≈ 0.37 (θ = 21.8°) and a stepped invert (Fig. 1b). Previous experiments were conducted in the same channel by Chanson and Toombes (2001, 2002) and Gonzalez (2005). Waters were supplied from a large feeding basin leading to a sidewall convergent with a 4.8:1 contraction ratio. The test section consisted of a broad-crested weir (1 m wide, 0.6 m long, with upstream rounded corner) followed by ten identical steps (h = 0.1 m, l = 0.25 m) made of marine ply. The stepped chute was 1 m wide with perspex sidewalls followed by a horizontal concrete canal ending in a sump pit.
The water was delivered by a pump controlled with an adjustable frequency AC motor drive, enabling an accurate discharge adjustment in a closed-circuit system. Further details and the full data set were reported by Carosi and Chanson (2006).
2.2 Instrumentation
Clear-water flow depths were measured with a point gauge. The discharge was measured from the upstream head above the crest with an accuracy of about 2%. The discharge measurements were derived from Gonzalez (2005) detailed velocity distribution measurements on the broad-crested weir.
The air–water flow properties were measured with two types of conductivity probes: single-tip and dual-tip probes (Fig. 2). Basic air–water flow measurements were performed with the single-tip conductivity probes (needle probe design). Figure 2a shows two single-tip conductivity probes side-by-side. Each probe consisted of a sharpened rod (Ø = 0.35 mm) coated with non-conductive epoxy set into a stainless steel surgical needle acting as the second electrode. Additional measurements were performed with some double-tip conductivity probes (Fig. 2b). Each sensor consisted of a sharpened rod (platinum wire Ø = 0.25 mm). The longitudinal spacing between the probe sensors was measured with a microscope and this yielded Δx = 7.0 and 9.6 mm for each of the double-tip probes.
All the probes were excited by an electronic system (Ref. UQ82.518) designed with a response time less than 10 μs and calibrated with a square wave generator. The measurements were conducted on the channel centreline (z = 0). For some experiments, a second identical probe was placed beside the first one with the probe sensors at the same vertical and streamwise distances y and x, respectively, and separated by a transverse distance Δz (Fig. 2).
For all experiments, each probe sensor was scanned at 20 kHz for 45 s.
2.3 Signal processing
The measurement principle of conductivity probes is based upon the difference in electrical resistivity between air and water. Since the resistance of water is one thousand times lower than the resistance of air, the time-variation of the voltage output has a “square-wave” shape. Each steep drop of the signal corresponds to an air bubble pierced by the probe tip. Herein the air–water flow properties were calculated using a single threshold technique for all void fractions. The threshold was set at about 45–55% of the air–water voltage range. A sensitivity analysis was conducted with thresholds between 40 and 60% of the voltage range, and the results showed little effect of threshold on the air–water flow properties (Toombes 2002). A similar finding was obtained by Herringe and Davis (1974) with threshold between 20 and 70% of the air–water voltage range.
The air concentration or void fraction C is the proportion of time that the probe tip is in the air. The bubble count rate F is the number of bubbles impacting the probe tip per second. The air–water interfacial velocities were deduced from a correlation analysis between the two sensors of the dual-tip probe (Chanson 1997a, 2002; Crowe et al. 1998). The time averaged interfacial velocity equals:
where T is the air–water interfacial travel time for which the cross-correlation function is maximum and Δx the longitudinal distance between probe sensors (Fig. 2b). Turbulence levels may be derived from the relative width of the cross-correlation function:
where τ0.5 is the time scale for which the cross-correlation function is half of its maximum value, such as R xy(T + τ0.5) = 0.5R xy(T), R xy is the normalised cross-correlation function, and T 0.5 is the characteristic time for which the normalised auto-correlation function equals: R xx(T 0.5) = 0.5 (Fig. 2b). While Eq. 2 might not be equal to the turbulence intensity u′/V, it is an expression of some turbulence level and average velocity fluctuations (Chanson and Toombes 2002).
More generally, when two probe sensors are separated by a transverse or streamwise distance Y, their signals may be analysed in terms of the auto-correlation and cross-correlation functions R xx and R xy, respectively (Fig. 2). Herein the original data of 900,000 samples were segmented into fifteen non-overlapping segments of 60,000 samples because the periodogram resolution is inversely proportional to the number of samples and it could be biased with large data sets (Hayes 1996; Gonzalez 2005). Further, the correlation analyses were conducted on the raw probe output signals. Basic correlation analysis results included the maximum cross-correlation coefficient (R xy)max, and the correlation times T xx and T xy, where
where R xx is the normalised auto-correlation function, t the time lag, and R xy the normalised cross-correlation function between the two probe output signals (Fig. 2). The auto-correlation integral time T xx characterises the longitudinal bubbly flow structure. The cross-correlation time scale T xy is a function of the probe separation distance Y. The probe separation distance Y is also denoted Δz for the transverse separation distance and Δx for the streamwise separation.
In the present study, identical experiments were repeated with several separation distances Y (Y = Δz or Δx) (Table 1). An integral length scale may be derived as
The corresponding integral time scale is:
An advection integral length scale is
where V is the advective velocity magnitude. The physical significance of L xy, T and L xx is discussed later.
2.4 Initial flow conditions
Experiments were conducted for a range of flow rates although the focus was on the highly aerated skimming flows (Table 1). Detailed measurements were performed for flow rates between 0.09 and 0.18 m3/s corresponding to dimensionless discharges d c/h = 1.0–1.57 and flow Reynolds numbers Re = ρw U w D H /μw between 3.8E+5 and 7.1E+5, where d c is the critical flow depth, h the step height, U w the depth-averaged velocity, D H the hydraulic diameter, and ρw and μw are the water density and dynamic viscosity, respectively. Present measurements were performed systematically at step edges downstream of the inception point of free-surface aeration (Fig. 1b).
3 Experimental results
3.1 Basic flow patterns
The basic flow regimes were inspected in a series of preliminary experiments with discharges ranging from 0.008 to 0.180 m3/s. For small flow rates (Re < 1.4E+5), the waters flowed as a succession of free-falling jets that was typical of a nappe flow regime. For some intermediate discharges (1.4E+5 < Re < 3.6E+5), the flow had a chaotic behaviour characterised by strong splashing and droplet projections downstream of the inception point of free-surface aeration. For larger flows (Re > 3.6E+5), the waters skimmed above the pseudo-bottom formed by the step edges (Fig. 1). The skimming flows were characterised by strong cavity recirculation with three-dimensional vortical patterns. These were best seen next to the inception point of free-surface aeration. Overall the results in terms of flow regimes and changes between flow regimes were very close to the earlier observations of Chanson and Toombes (2001) and Gonzalez (2005) in the same facility.
3.2 Distributions of void fraction and bubble count rate
Experimental observations demonstrated substantial free-surface aeration immediately downstream of the inception point of free-surface aeration while some sustained flow aeration was observed further downstream. This is illustrated in Fig. 3 where the dimensionless distributions for void fraction C and bubble count rate Fd c/V c are presented as functions of y/Y 90 for several successive step edges for the same flow rate, where y is the distance normal to the pseudo-bottom formed by the step edges, Y 90 is the characteristic distance where C = 0.90, and d c and V c are, respectively, the critical flow depth and velocity defined as
with Q w the water discharge, g the gravity acceleration and W the channel width. For the data shown in Fig. 3a, the flow aeration was nil at step edge 6 immediately upstream of the inception point. Between step edges 6 and 7, some strong self-aeration took place. The amount of entrained air and the mean air content were about constant between the step edges 7 and 10, and the depth-averaged void fraction C mean was about 0.35–0.37.
The void fraction profiles showed consistently a similar shape (Fig. 3). The dimensionless distributions exhibited a S-shape profile that was observed in previous skimming flow studies: e.g., Ruff and Frizell (1994), and Chanson and Toombes (1997). For all the data, the void fraction distribution measurements compared well with an analytical solution of the advective diffusion equation for air bubbles:
where K′ is an integration constant and D o is a function of the depth-averaged void fraction C mean only:
Equation 10 was first developed by Chanson and Toombes (2002) and is compared with dimensionless void fraction data in Fig. 3.
The dimensionless distributions of bubble count rate showed consistently a characteristic shape with a maximum value observed for void fractions between 40 and 60% (Fig. 3). A similar result was observed in smooth chute and stepped spillway flows (e.g. Chanson 1997b; Chanson and Toombes 2002; Toombes 2002). The relationship between bubble frequency and void fraction was approximated by a parabolic shape:
For the present study, the maximum bubble count rate F max was observed for 0.35 ≤ C ≤ 0.6 although most data sets were within 0.4 ≤ C ≤ 0.5. Toombes (2002) demonstrated some theoretical validity of Eq. 14 and he extended the reasoning to air–water flow situations when the maximum bubble count rate is observed for C ≠ 0.5 (Toombes 2002, pp 190–195).
3.3 Distributions of interfacial velocity and turbulence level
At each step edge, the time-averaged velocity and turbulent velocity fluctuation profiles showed some characteristic shapes (Fig. 4a). The interfacial velocity distributions presented a smooth shape similar to earlier results on stepped chutes (e.g. Boes 2000; Chanson and Toombes 2002; Gonzalez 2005). Importantly, the velocity distributions showed some self-similarity (Fig. 4b). All the data followed closely a power-law function for y/Y 90 ≤ 1. For y/Y 90 > 1, the velocity profile was quasi-uniform. That is
where V 90 is the characteristic air–water velocity at y = Y 90. Several researchers observed the velocity profile described by Eq. 15, but few studies documented the velocity distribution in the upper spray region (Gonzalez 2005). Present data are compared with Eqs. 15 and 16 in Fig. 4b. For the present experiments, the exponent N was about 10, although it varied between a step edge and the next consecutive step edge for a given flow rate. The variations was believed to reflect some flow interactions between adjacent shear layers and cavity flows.
In the upper flow region (i.e. y > Y 90), the data showed a quasi-uniform velocity profile (Eq. 16). The finding was consistent with visual observations of the flow structure consisting predominantly of individual water droplets and packets surrounded by air. The result tended to suggest that most spray droplets were in a free-fall trajectory since the ejected droplets had a response time of nearly two orders of magnitude larger than that of the surrounding air flow.
The turbulent intensity profiles exhibited some maximum turbulence level for 0.3 ≤ y/d c ≤ 0.4 which corresponded to about C ≈ 0.4–0.6 (Fig. 4a). The experimental data showed further a strong correlation between the turbulence intensity Tu and the bubble count rate. This is illustrated in Fig. 5 presenting the turbulence intensity Tu as a function of the dimensionless bubble count rate Fd c/V c. The data collapsed reasonably well into a single curve:
Equation 17 reflects a monotonic increase in turbulence levels with an increase in bubble count rate. The limit for F = 0 (i.e. Tu = 0.25) is close to monophase flow measurements on a stepped chute upstream of the inception point of free-surface aeration (Ohtsu and Yasuda 1997; Amador et al. 2004). It is hypothesised that the large number of air–water interfaces, and the continuous deformations of the air–water interfacial structure generated large turbulence levels measured by the intrusive phase-detection probe (i.e. double-tip conductivity probe).
3.4 Correlation functions and time scales
The correlation functions exhibited similar patterns for all investigated flow conditions with both transverse and longitudinal separations. The auto-correlation functions were best fitted by
where τ is the time lag and T 0.5 is the time lag for which R xx = 0.5. The cross-correlation functions exhibited clearly a marked maximum (R xy)max which decreased with increasing sensor separation Y as illustrated in Fig. 6. (R xy)max reached the largest values for C = 0.4–0.6, and this is linked to the presence of maximum bubble count rate. The cross-correlation functions followed closely a Gaussian error function:
where (R xy)max is the maximum normalised cross-correlation value observed for the time lag τ = T, and τ0.5 is the time lag for which R xy = 0.5(R xy)max (Fig. 2). The finding (Eq. 19) was observed systematically for (τ−T)/ τ0.5 < 2. Note that some earlier studies reported streamwise cross-correlation function data that followed similarly a Gaussian error function (e.g. Chanson 2002; Chanson and Toombes 2002).
Typical distributions of correlation time scales T xx and T xy are presented in Fig. 7. Figure 7a shows the vertical distributions of correlation time scales for several transverse spacings with identical flow conditions. Note that the correlation time scales are presented in a dimensional form (units: s). T xx represents a time scale of the longitudinal bubbly flow structure and of the eddies advecting the air–water interfaces in the streamwise direction. The cross-correlation time scale T xy represents a characteristic time of the vortices with a length scale Y advecting the air–water structures where the length scale Y is the probe separation distance.
Figure 7b presents a typical relationship between void fraction and correlation time scales at a given flow cross-section. Both the distributions of auto- and cross-correlation time scales T xx and T xy presented a parabolic shape for 0 ≤ C ≤ 0.95 at all step edges and for all investigated flow rates. This is seen in Fig. 7b. However a marked change of shape for the auto-correlation time scale T xx distribution was systematically observed in the upper spray region (C > 0.95–0.97). This change in profile is highlighted in Fig. 7a, b with an arrow. It is suggested that the pattern may indicate a change of the spray structure in the upper spray region which consisted primarily of ejected droplets that did not interact with the rest of the flow.
The relationship between the cross-correlation time scale and the void fraction were closely fitted by:
where (T xy)max is the maximum cross-correlation time scale in the cross-section for a given separation distance Δz. Equation 20 is compared with experimental data in Fig. 7b. Experimental observations of maximum transverse time scale (T xy)max are reported in Table 2.
3.5 Turbulent time and length scales
The turbulent length and time scales, L xy and T, respectively, were calculated using Equs. 5 and 6 based upon correlation analyses conducted with several transverse separation distances Y. Typical results in terms of dimensionless turbulent length scale L xy/Y 90, integral turbulent time scale \({{\mathbf{T}}{\sqrt {g/Y_{{90}}}}}\) and advection length scale L xx/Y 90 are presented in Fig. 8. The measured void fraction data are also shown in Fig. 8.
The turbulent length scale L xy represents a characteristic dimension of the large vortical structures advecting the air bubbles and air–water packets. In bubbly flows, the turbulent length scales are closely linked with the characteristic sizes of the large-size eddies and their interactions with entrained air bubbles. This was evidenced by high-speed photographs demonstrating air bubble trapping in large eddies of developing mixing layers (e.g. Hoyt and Sellin 1989; Chanson 1997a). Herein the integral turbulent length scale L xy represented a measure of the size of large vortical structures advecting air bubbles in the skimming flow regime. The air–water turbulent length scale was closely related to the characteristic air–water depth Y 90: i.e., 0.05 ≤ L XV/Y 90≤ 0.2 (Fig. 8). This result was valid for both transverse and longitudinal length scales, and it was irrespective of the flow Reynolds numbers within the range of the experiments.
The turbulence time scale T characterises the integral turbulent time scale of the large eddies advecting the air bubbles and air–water particle clusters. The streamwise and transverse integral turbulent time scales were close, and the present data yielded typically 0.01 \({{\mathbf{T}}{\sqrt{g/Y_{{90}}}} \leq 0.06}\) (Fig. 8).
The advection length scale L xx is a characteristic longitudinal size of the large advecting eddies. Within Taylor’s hypothesis of separate and additive advection and diffusion processes, it would be expected that the advection and turbulent length scales are about equal: L xy ≈ L xx. The result was valid for C < 0.95, although some significant deviation was observed in the upper spray region (C > 0.95–0.97) (Fig. 8).
The relationships between the integral length scales L xy and L xx and integral time scale T, and the void fraction exhibited a “skewed parabolic shape” with maxima occurring for void fractions between 0.6 and 0.7. This is illustrated in Fig. 9. The dimensionless distributions of transverse turbulent length scale L xy/Y 90, transverse integral turbulent time scale \({{\mathbf{T}}{\sqrt {g/Y_{{90}}}}}\) and advection length scale L xx/Y 90 were best correlated by:
where (L xy)max, T max, and (L xx)max are the characteristic maxima in the cross-section. Experimental observations of (L xy)max, T max, and (L xx)max are regrouped in Table 3. Equation (21) to (23) are compared with data in Fig. 9. Note that Equations (22) and (23) are not valid in the upper spray region (C > 0.95–0.97).
The high-velocity open channel flows on the stepped channel were highly turbulent (Fig. 4a). Present results demonstrated that the high levels of turbulence were associated directly with large scale turbulence. In particular, the intermediate region (0.3 < C < 0.7) between bubbly and spray regions seemed to play a major role in the development the large vortices. Turbulence level maxima were observed for 0.4 < C < 0.5, while maximum integral turbulent scales were seen for 0.6 < C < 0.7 (Fig. 9).
4 Discussion
4.1 The upper spray region
In the present study, detailed air–water flow measurements were conducted in the spray region (Fig. 10a) defined herein as C > 0.7 for void fractions C up to 0.999 corresponding to y/Y 90 up to 2.5. The experimental data showed some distinctive features in the upper spray region defined as C > 0.95–0.97, especially in terms of droplet chord size distributions and advection integral length scale distributions.
In the lower spray region (0.7 < C < 0.95), the probability distribution functions of water chord were skewed with a preponderance of small droplets relative to the mean and they followed closely a log-normal distribution. The distributions of advection length scale L xx showed a decrease in dimensionless length scales L xx/Y 90 with increasing distance y/Y 90 and decreasing liquid fraction (1−C).
Some different results were observed in the upper spray region (C > 0.95–0.97). The probability distribution functions of droplet chords were relatively flat and did not follow a log-normal distribution. The PDF maxima were about 0.1–0.15 and most droplet chords were between 0.5 and 8 mm. For C > 0.95–0.97, the distributions of advection integral length scale showed increasing length scale with decreasing liquid fraction (1−C) (Figs. 8, 9). The result might suggest the existence of longitudinal “streaks” of water drops.
It is believed that the contrasting features of the upper spray region reflected a change in the microscopic flow structure. That is, the upper spray region consisted primarily of ejected water droplets that did not interact with the main flow nor with the surrounding air. These droplets tended to follow some ballistic trajectory as illustrated in Fig. 10b, c. Their “history” was dominated by the initial ejection process and possibly by droplet collisions.
4.2 Self-similarity in air–water flow properties
A self-similar process is one whose spatial distribution of properties at various times can be obtained from one another by a similarity transformation (Barenblatt 1994, 1996). Self-similarity is a powerful tool in turbulence flow research, and skimming flows on a stepped chute are one type of turbulent flows involving a wide spectrum of spatial and temporal scales. The non-linear interactions among vortices and particles at different scales lead to a complicated flow structure, and relationships among flows at different scales are of crucial significance. These play also a major role in comparing analytical, experimental and numerical results as these results are for different scales. For example, most stepped spillway applications are for prototype flow conditions with flow Reynolds number between 1E+6 and more than 1E+9 that cannot be modelled numerically nor physically.
In the present study, self-similarity was observed in terms of the distributions of air–water flow properties. Table 4 summarises some basic self-similarity equations that were observed during the present work. Self-similarity is illustrated for example in Figs. 3, 4b, 5, 7a, 9, and 11. These self-similar relationships were observed at both macroscopic and microscopic levels. For example, the distributions of void fraction and interfacial velocity at a macroscopic level, and the cross-correlation function and probability distribution functions of particle chords at a microscopic level (Table 4).
Self-similarity is closely linked with dynamic similarity. Some researchers argued that it is nearly impossible to achieve a true dynamic similarity in stepped spillway models because of number of relevant dimensionless parameters (Boes 2000; Chanson 2001; Chanson and Gonzalez 2005). However the present experimental results showed a number of self-similar relationships that remain invariant under changes of scale: i.e., they have scaling symmetry which led in turn to remarkable application at prototype scales (Table 4). Clearly the present results are most significant. They provide a picture general enough to be used, as a first approximation, to characterise the air–water flow field in similar stepped spillway structures irrespective of the physical scale.
5 Conclusion
Detailed gas–liquid flow measurements were performed in high-velocity open channel flows above a steep stepped channel. The experiments were conducted with flow Reynolds numbers ranging from 3.8E+5 to 7.1E+5, and measurements were performed with phase-detection intrusive probes: single-tip conductivity probes (Ø = 0.35 mm) and double-tip conductivity probes (Ø = 0.25 mm). An advanced signal processing technique with new signal correlation analyses was developed and applied systematically.
The air water flow properties presented some basic characteristics that were qualitatively and quantitatively similar to previous studies in skimming flows. These included the distributions of void fraction, bubble count rate and interfacial velocity. Some self-similar relationships were observed systematically at both macroscopic and microscopic levels (Table 4). These included the distributions of void fraction, bubble count rate, interfacial velocity and turbulence level at a macroscopic scale, and the bubble chord distributions and auto- and cross-correlation functions at the microscopic level. The experimental results showed a number of self-similar relationships that remained invariant under changes of scale. The present findings are significant because they provides a picture general enough to characterise the air–water flow field in prototype stepped spillways.
The correlation analyses yielded a characterisation of the large eddies advecting the bubbles. Basic results included the integral turbulent length and time scales. The turbulent length scales characterised some measure of the size of large vortical structures advecting air bubbles in the skimming flows, and the data were closely related to the characteristic air–water depth Y 90: i.e. L xy/Y 90 ≈ 0.05–0.2. The dimensionless integral turbulent time scales were within \({0.01\leq{\mathbf{T}}{\sqrt{g/Y_{{90}}}}}\leq0.06.\) The results were irrespective of the Reynolds numbers within the range of the experiments. The measurements highlighted further some maximum turbulence intensities, and maximum integral time and length scales in the intermediate region between the spray and bubbly flow regions (i.e. 0.3 < C < 0.7). The findings suggested that turbulent dissipation by large-scale vortices may be a significant process in the intermediate zone.
In the spray region, present results highlighted the existence of an upper spray region for C > 0.95–0.97 in which the distributions of droplet chord sizes and integral advection scales (T xx, L xx) presented some marked differences. It is suggested that these patterns highlighted a change in spray structure, whereby the upper spray region consisted primarily of ejected droplets following ballistic trajectories.
Abbreviations
- C :
-
void fraction defined as the volume of air per unit volume of air and water; it is also called air concentration or local air content
- C mean :
-
depth-average void fraction defined in terms of Y 90:C mean = 1 − d/Y 90
- D H :
-
hydraulic diameter (m) also called equivalent pipe diameter
- D o :
-
dimensionless constant
- d :
-
equivalent clear water flow depth defined as \({d = {\int\nolimits_{C = 0}^{C = 0.90} {(1 - C)\,\hbox{d}y}}}\)
- d c :
-
critical flow depth (m): \({d_{\rm c} = \root 3\of{{\it{Q}_{\it w} ^{2} /(gW^{2})}}}\)
- F :
-
air bubble count rate (Hz) or bubble frequency defined as the number of detected air bubbles per unit time
- F max :
-
maximum bubble count rate (Hz) at a cross-section
- g :
-
gravity constant: g = 9.80 m/s2 in Brisbane, Australia
- h :
-
vertical step height (m)
- K′:
-
dimensionless integration constant
- K*:
-
dimensionless constant
- L xx :
-
air–water advection integral length scale (m): L xx = VT xx
- L xy :
-
transverse/streamwise air–water integral turbulent length scale (m): \({L_{{\rm xy}} = {\int\limits_{Y = 0}^{Y_{{\rm max}}} {(R_{{\rm xy}})_{{\rm max}}\,\hbox{d}Y}}}\)
- (L xx)max :
-
maximum advection air–water length scale (m) in a cross-section
- (L xy)max :
-
maximum air–water integral length scale (m) in a cross-section
- l :
-
horizontal step length (m)
- N :
-
power law exponent
- Q w :
-
water discharge (m3/s)
- Re :
-
Reynolds number defined in terms of the hydraulic diameter
- R xx :
-
normalised auto-correlation function
- R xy :
-
normalised cross-correlation function between two probe output signals
- (R xy)max :
-
maximum cross-correlation between two probe output signals
- S o :
-
bed slope: S o = sin θ
- T :
-
time lag (s) for which R xy = (R xy)max
- T :
-
integral turbulent time scale (s) characterising large eddies advecting the air bubbles
- Tu:
-
turbulence intensity defined as Tu = u′/V
- T xx :
-
auto-correlation time scale (s): \({T_{{\rm xx}} = {\int\nolimits_{\tau = 0}^{\tau = \tau (R_{{\rm xx}} = 0)} {R_{{\rm xx}} (\tau)\,\hbox{d}\tau}}}\)
- T xy :
-
cross-correlation time scale (s): \({T_{{\rm xy}} = {\int\nolimits_{\tau = \tau (R_{{\rm xy}} = (R_{{\rm xy}})_{{\rm max}})}^{\tau = \tau (R_{{\rm xy}} = 0)} {R_{{\rm xy}} (\tau)\,\hbox{d}\tau}}}\)
- T 0.5 :
-
characteristic time lag (s) for which R xx = 0.5
- T max :
-
maximum integral time scale (s) in a cross-section
- (T xy):
-
maximum cross-correlation time scale (s) in a cross-section
- U w :
-
flow velocity (m/s): U w = Q w /(dW)
- u′:
-
root mean square of longitudinal component of turbulent velocity (m/s)
- V :
-
interfacial velocity (m/s)
- V c :
-
critical flow velocity (m/s)
- V 90 :
-
characteristic interfacial velocity (m/s) where C = 0.90
- W :
-
channel width (m)
- x :
-
distance along the channel bottom (m)
- Y :
-
separation distance (m) between two phase-detection probe sensors
- Y 90 :
-
characteristic depth (m) where the void fraction is 90%
- y :
-
distance (m) measured normal to the invert (or channel bed)
- y′:
-
dimensionless distance (m) normal to the invert (or channel bed): y′ = y/Y 90
- z :
-
transverse distance (m) from the channel centreline
- Δx :
-
streamwise separation distance (m) between sensor
- Δz :
-
transverse separation distance (m) between sensor
- μ:
-
dynamic viscosity (Pa s)
- μw :
-
water dynamic viscosity (Pa s)
- θ:
-
angle between the pseudo-bottom formed by the step edges and the horizontal
- ρ:
-
density (kg/m3)
- ρw :
-
water density (kg/m3)
- τ :
-
time lag (s)
- τ 0.5 :
-
characteristic time lag τ for which R xy = 0.5(R xy)max
- χ:
-
dimensionless parameter: χ = K′ − y′/(2D o) + (y′ − 1/3)3 /(3D o)
- Ø:
-
diameter (m)
- w:
-
water flow
- xx:
-
auto-correlation of reference probe signal
- xy:
-
cross-correlation
- 90:
-
flow conditions where C = 0.90
References
Amador A, Sanchez-Juny M, Dolz J, Sanchez-Tembleque F, Puertas J (2004) Velocity and pressure measurements in skimming flow in stepped spillways. In: Proceedings of the international conference on hydraulics of dams and river structures, Tehran, Iran, Balkema Publ., Netherlands, pp 279–285
Barenblatt GI (1994) Scaling, phenomena in fluid mechanics. Inaugural lecture delivered before the University of Cambridge on 3 May 1993, Cambridge University Press, UK, 49 pp
Barenblatt GI (1996) Scaling, self-similarity, and intermediate asymptotics. Cambridge University Press, UK, 386 pp
Boes RM (2000) Scale effects in modelling two-phase stepped spillway flow. In: Proceedings of the international workshop on hydraulics of stepped spillways, Balkema Publ., Zürich, Switzerland, pp 53–60
Cain P, Wood IR (1981a) Instrumentation for aerated flow on spillways. J Hydraul Div 107:1407–1424
Cain P, Wood IR (1981b) Measurements of self-aerated flow on a spillway. J Hydraul Div 107:1425–1444
Carosi G, Chanson H (2006) Air–water time and length scales in skimming flows on a stepped spillway. Application to the spray characterisation. Report no. CH59/06, Division of Civil Engineering, The University of Queensland, Brisbane, Australia, July, 142 pp
Chang KA, Lim HJ, Su CB (2003) Fiber optic reflectometer for velocity and fraction ratio measurements in multiphase flows. Rev Scientific Instrum 74:3559–3565, Discussion: 2004, 75:284–286
Chanson H (1997b) Air bubble entrainment in open channels. Flow structure and bubble size distributions. Int J Multiphase Flow 23:193–203
Chanson H (1997a) Air bubble entrainment in free-surface turbulent shear flows. Academic, London, UK, 401 pp
Chanson H (2001) The hydraulics of stepped chutes and spillways. Balkema, Lisse, The Netherlands, 418 pp
Chanson H (2002) Air–water flow measurements with intrusive phase-detection probes. Can we Improve their interpretation? J Hydraul Eng 128:252–255
Chanson H, Gonzalez CA (2005) Physical modelling and scale effects of air–water flows on stepped spillways. J Zhejiang Univ Sci 6A:243–250
Chanson H, Toombes L (1997) Flow aeration at stepped cascades. Research report no. CE155, Department of Civil Engineering, University of Queensland, Australia, June, 110 pp
Chanson H, Toombes L (2002) Air–water flows down stepped chutes: turbulence and flow structure observations. Int J Multiphase Flow 27:1737–1761
Crowe C, Sommerfield M, Tsuji Y (1998) Multiphase flows with droplets and particles. CRC Press, Boca Raton, USA, 471 pp
Euh DJ, Yun BJ, Song CH (2006) Benchmarking of the five-sensor probe method for a measurement of an interfacial area concentration. Exp Fluids 41:463–478
Gonzalez CA (2005) An experimental study of free-surface aeration on embankment stepped chutes. Ph.D. thesis, Department of Civil Engineering, The University of Queensland, Brisbane, Australia, 240 pp
Hayes MH (1996) Statistical, digital signal processing and modeling. Wiley, New York, USA
Herringe RA, Davis MR (1974) Detection of instantaneous phase changes in gas–liquid mixtures. J Phys E: Sci Inst 7:807–812
Hoyt JW, Sellin RHJ (1989) Hydraulic jump as ’mixing layer’. J Hydraul Eng 115:1607–1614
Jones OC, Delhaye JM (1976) Transient and statistical measurement techniques for two-phase flows: a critical review. Int J Multiphase Flow 3:89–116
Kim S, Fu XY, Wang X, Ishii M (2000) Development of the miniaturized four-sensor conductivity probe and the signal processing scheme. Int J Heat Mass Transf 43:4101–4118
Ohtsu I, Yasuda Y (1997) Characteristics of flow conditions on stepped channels. In: Proceedings of the 27th IAHR Biennial Congress, San Francisco, USA, Theme D, pp 583–588
Ruff JF, Frizell KH (1994) Air concentration measurements in highly-turbulent flow on a steeply-sloping chute. In: Proceedings of the hydraulic engineering conference, vol 2. ASCE, Buffalo, USA, pp 999–1003
Toombes L (2002) Experimental study of air–water flow properties on low-gradient stepped cascades. Ph.D. thesis, Department of Civil Engineering, The University of Queensland, Brisbane, Australia
Acknowledgments
The writers acknowledges the technical assistance of Graham ILLIDGE and Clive BOOTH.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Chanson, H., Carosi, G. Turbulent time and length scale measurements in high-velocity open channel flows. Exp Fluids 42, 385–401 (2007). https://doi.org/10.1007/s00348-006-0246-2
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00348-006-0246-2