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Flow, flow transition and runout distances of flowing avalanches

Published online by Cambridge University Press:  20 January 2017

B. Salm*
Affiliation:
Eidgenössisches Institut für Schnee- und Lawinenforschung, CH-7260 Weissfluhjoch/Davos, Switzerland
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Abstract

A simple quasi one-dimensional model of flowing avalanches is presented. It is a further development of that used in the Swiss Guidelines for practitioners. It is shown that shearing in avalanche movement is concentrated near the ground and that, due to the geometrical roughness of the ground, a flow resistance proportional to the square of velocity must be taken into account in addition to dry friction. For the change of flow on changing slope angles it is demonstrated that under certain conditions for internal friction a “normal” flow on a flat lower part can no longer be attained; the avalanche behaves like a rigid body. The runout distance is in fair agreement with the Guidelines if a larger internal friction is used. The main differences lie in much smaller deposition depths and smaller velocities during runout.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1993

Introduction

In Switzerland a simple model for flowing avalanches is widely used for practical purposes (Reference SalmSalm and others, 1990). This model — designated as Guidelines — is based on theoretical considerations, field measurements of velocities, and examination of several hundred observed avalanches, especially runout distances. Further developments will be presented and existing relations are specified more precisely. As the flow depth of an avalanche is much smaller than its length, a quasi one-dimensional flow is assumed.

Flow Profile

The main question here is the distribution of shearing within the moving snow, i.e. internal shearing within the avalanching snow versus shearing near the ground (sliding). The only measurement in a natural avalanche by Reference GublerGubler and others (1986) shows a shear concentration very close to the ground and nearly no internal shearing.

Moving snow in natural avalanches seems to be not a homogeneous but a structured mass. Even in a more or less steady movement, field tests (e.g. Reference Schaerer and SalwaySchaerer and others, 1980) show not constant but oscillating impact pressures with pronounced peaks in rapid sequences. This can be interpreted as an effect of lumps of snow much larger than single snow grains.

We consider, therefore, avalanching snow as consisting of clods of snow, idealized as spheres with a uniform diameter, ϕ of an order of magnitude of 0.1 m. Contact forces between spheres are assumed to be dry friction, characterized by the internal friction angle, ϕ, and impact forces with a coefficient of restitution e ~ 0 (i.e. snow and not single ice grains). Dry friction acts in the contact plane and impact forces perpendicular to it. The driving force is gravity.

Roughly seen, an internal movement parallel to the slope is only possible if ϕ is smaller than the slope angle, ψ Internal friction has never been measured directly, but from observations of avalanche deposits and measurements by Reference RochRoch (1966), ϕ can be estimated at least to be about 25°, i.e. about the slope of avalanche tracks. Therefore an internal shearing movement of the overburden seems improbable, especially in the runout zone where ψ ≤ 15°.

Sliding near ground seems to be the decisive process determining avalanche speed. To get a qualitative insight, a simple model analogous to that of Reference BagnoldBagnold (1954, 1966) is used (Salm, unpublished a). To estimate the flow resistance due to impact of the moving snow, the roughness of the ground is represented by obstacles protruding from the ground with a mean distance of Δr in flow direction x1 ( Figure 1). The heights of these obstacles are at least of the same order of magnitude as the clods of snow. Flow depth, d, and coordinate x2 are perpendicular to the slope.

Fig.1 . Model for shearing near the ground.

If the speed over ground is vg , then vg /Δr collisions in unit time occur. The change of momentum in indirection per sphere with e = 0 is mvg cos2 α The impact angle, α, is between vg and the normal of the contact surface and m is the mass of a particle with density ρs of snow. The number of spheres per unit area parallel to ground is (α1ϕ)−2

The total shear resistance due to impact is then

(1)

Introducing the mass of a sphere

and the number of spheres per unit volume
we get for the mean density of flowing snow

and therefore

(2)

This is the well known “turbulent” friction, first stated by Reference VoellmyVoellmy (1955). He, however, introduced this term in analogy to turbulent open-channel flow in hydraulics (Chézy equation).

The above relations are complicated by the fact that a 1, a 2 and α are functions of speed (personal communication from J. Dent), so that ρm and ξ become velocity-dependent too.

It is to be expected that α (180° ≥ α ≥ 90°) decreases with higher velocities. Furthermore, the terrain roughness will be smoothed to a certain degree by deposited snow, depending on obstacle heights.

If τ of Equation (2) decreases to zero (for α = 90° or Δr = ∞) only dry friction on ground remains as resistance. The coefficient of dry friction, μ, of sliding is well known from observations in runout zones. Its value 0.155 ≤ μ ≤ 0.30 is much less than that of tan ϕ (Reference SalmSalm and others, 1990). Adding this dry friction to the “turbulent” friction yields

(3)

Observations of real avalanches Reference Gubler, Hiller, Klausegger and Suter(Gubler and others, 1986) are at least not in contradiction with the described concept. A careful inspection of these data shows that at least two resistances must occur. In a fracture zone with smooth terrain, dry friction dominates and leads to high accelerations. As soon as rugged terrain is reached the resistance increases, obviously due to an additional velocity-dependent force.

It can be concluded that the velocity profile of a flowing avalanche can be idealized by a rectangular shape with Equation (3) as average velocity. (This holds as long as the slope is not too steep, say ψ < 35°.) The coefficient μ is mainly connected to snow properties, whereas ξ depends mainly on terrain geometry. If the roughness is not large, ξ increases with speed so that asymptotically only dry-friction resistance remains (personal communication from J. Dent).

Flow Transition

We assume that over a limited time the discharge, Q (m3 s−1), in a flowing avalanche is constant (Salm, 1972). With a homogeneous and constant density (ρm = ρ) and with a nearly one-dimensional movement (∂d/∂x ∂ 1) we have

(4)

where Β is the width of the avalanche.

On a uniform slope angle ψ0 , the velocity with Equations (3) and (4) is

(5)

As soon as ψ0 changes to ψu in a point A, the velocity changes gradually from ν 0 to νu , and with this the flow depth from d0 to du.

We consider a volume element on the slope ψu fixed in the space. Its length in flow direction x1 is d and we assume a quasi one-dimensional movement in the x 1x2 plane.

We start from the global form of momentum theorem,

(6)

with time, t, volume, V, surface, F, stress, σjk , unit vector, νj (with positive direction to the outer side of the volume), and with the body force, Kk.

In the plane x2 x3 perpendicular to the flow direction x1 we have the resultant pressure force of

with
(7)

if ψ0 > ψu (passive snow pressure). This represents the upper limit of the force, corresponding to the Colomb–Mohr criterion. (In a flow on an infinite slope, λ must be about unity.)

If a steady movement is assumed, the following expressions are obtained (with x1 = x and ν1 = ν):

and from this the differential equation

with the dimensionless velocity u = ν/νu and

With the initial condition u0 = ν0 /νu the solution is

(8)

The “normal” flow on ψu with u = 1 will theoretically be attained as x → ∞.

Figure 2 shows an example for the decrease of u for a flow from steeper to flatter terrain with different values of λ. This decrease is faster for larger λ because of the larger passive snow pressure on the flat part. There is however a restriction: if λ is too large “normal” flow on ψu cannot be attained. The limiting value for λ can be seen from Equation (8). If b + c = 0 then

(9)

For larger values than Equation (9) the flow on ψu continues with υ0 and d0. The driving force

— too small to maintain a steady flow — is enlarged by the passive snow pressure at point A given by d0 . After a critical length, this pressure will be too small to maintain this “deficit” flow; d0 will be gradually enlarged to du so that “normal” flow is established on ψu.

Fig.2 . Flow transition for different values of λ.

The assumed parameters for μ and ξ in Figure 2 are empirical ones from observed avalanches as given in the Guidelines (Salm and others, 1990). From Equation (2) a value for ξ = 1000 m s−2 would be obtained for a2 = 0.8, Δr/ϕ = 10 and α = 110°.

The steepest gradient of u in Figure 2 occurs for x = 0 and λ = 20 which gives ∂d/∂x = 10−2. The assumption of a quasi one-dimensional flow is therefore fullfilled.

The dimensionless quantity in Equation (8),

is used in practical calculations to decide whether or not “normal” flow is reached on a certain slope after a certain length x. In the Guidelines a value of 0.7 is given after which the velocity differs less than 10% from “normal” flow conditions. This value has been calculated earlier by Salm (unpublished b) with a simpler approach.

The influence of λ has been neglected and g/ξ was assumed to be very small, so that b = 0 and c = 1, which delivers the differential equation

with a solution similar to Equation (8). Figure 2 shows that 0.7 is the maximum for λ ≥ 10. It is however too small for λ = 2.5, a value which is probably not realistic for a pressure zone (see section below).

To avoid difficulties in estimating the transition zone with a simple rule, Equation (8) could be used directly to calculate the velocities on limited sections with constant slope, however with considerable effort.

Runout Distance

The situation is similar to that with flow transition: at a point Ρ the slope angle changes from ψ 0 to ψu , however for ψu the condition

(10)

must be fulfilled, i.e. not a driving but a retarding force must occur. This retarding force is originating from the velocity-independent dry friction, which is the only effective mechanism to slow down the movement to standstill on a slope inclined in direction of the speed. This is the runout situation observed for most avalanches. It may be remarked that Equation (10) allows a very simple measurement of the minimum acting friction coefficient of observed avalanches.

Again the mean density ρm = ρ is considered constant, and the length of the runout is about two orders of magnitude larger than d, so that again a quasi one-dimensional movement can be assumed.

The supply of avalanching snow at point Ρ is given by Q, which is constant for the time between the entrance of the snow at Ρ until the standstill.

The velocity of the snow mass between the front and Ρ is in every point constant but time-dependent. This can be justified with the often observed “train-like” behaviour in the runout: the movement seems similar to that of a rigid body. The reason for this lies in high internal friction angles plus (probably) a cohesion which may be created quickly in relatively slow-moving snow in flat terrain (Gubler, 1982).

The depth, d, in the runout is larger than the flow depth of the entering snow, dp , at P. This difference, Δd, is due to the velocity difference of υp at Ρ and υ of the retarding snow mass, and can be calculated approximately from the kinetic and pressure energy in analogy to hydraulics:

and yields

(11)

For our calculation we will assume a constant mean depth, dm , over the final runout distance, xs . A first assumption of dm will allow us to calculate υ and then to check this assumption and, if necessary, to correct it. Furthermore, it will be possible to check the total supply of mass at Ρ during the time interval until standstill, and then this mass can be compared with that obtained from Equation (11). These problems will be discussed later; at present we assume all kinetic energy from the velocity difference at Ρ is completely transferred into an increase of depth.

In the avalanche front the depth cannot be increased immediately; it will remain constant, equal to dp over a certain time or length. This length, Δ, is attained as soon as the increasing snow pressure at Ρ arrives at its maximum,

and is in equilibrium with flow resistance and driving force; thus
(12)

The theorem of momentum is formulated for unity width B. The distance of Ρ to the avalanche front is x + Δ and the mass is

The term ∂d/∂t is neglected and ∂υ/∂t = υ∂υ/∂x.

This leads to the differential equation

(13)

With the initial condition ν = υp for x = 0 we get the solution

(14)

with

and furthermore

A solution exists only with a positive V 2, thus runout condition (10) is fulfilled. For x → ∞ we get ν 2/V 2 = −1.

The total runout distance is xs = x0 + Δ, where x0 corresponds to ν 2 = 0 in (14) and Δ is taken from (12).

The calculation of the runout distance in the Guidelines (1990) is based on Salm (unpublished b). There only the runout of the constant front mass, ρdmΔ, is considered and the influence of the snow pressure at Ρ is neglected. For the velocity we arrived at

(15)

and for runout distance

(16)

with

(17)

The subscript G denotes values according to the Guidelines. The latter relation assumes a linear decrease of ν2 with x, based on the assumption that only dry friction is acting. The coefficient λ is fixed at 2.5. With the above formulas, and mainly with observed runout distances, the coefficients μ and ξ were calibrated. The agreement is satisfactory although the applied dm in (17) with λ = 2.5 seems to furnish too large values.

To compare the calibrated rules (15)–(17) with (12) and (14), the following examples have been calculated:

friction coefficients: μ = 0.155 ξ = 1000 m s−2;

discharge: Q/B = 10/50/l00/200 m2 s−1;

slope angle before Ρ: ψP = 25°;

slope angle in the runout zone: ψs = 0°/7.5°.

The agreement of xs from Equations (12) and (14) with xsG is surprisingly good, but only if the large value of λ = 20 (φ = 65°) is introduced. The ratio xs /xsG is 1.02 and 1.18 for ψ = 0° and 7.5° respectively, which means that for slopes ψs close to the critical value of tan−1 μ = 8.8° the runout distance becomes larger due to the snow pressure at P.

For xs the mean deposition depth dm is 2.5–2.8 times smaller than for xsG, according to observations a reasonable result.

The mean value dm was checked with Equations (14) and (11). The mean square of the velocity from (14) is

and

(18)

A good estimation for Δd is υp2 /(3.94gλ) and υp2 /(2.50) for λs = 0° and 7.5° respectively. For different values of ψs a linear interpolation will furnish satisfactory results.

Considering the conservation of mass we assume a constant supply Q/B = υpdp from the moment when the front passes Ρ until it reaches xs, therefore

and with this the average depth from supply

(19)

In Figure 3 the different depths, dm , dms and dmG are plotted as a function of Q/B and the two slope angles, ψs , of 0° and 7.5°.

It is clear that the depth from supply must be equal to or larger than the dynamic depth of (17) or (18). As it can be seen from Figure 3, dms is always larger than dm .

Fig.3 . Mean deposition depth of the present calculation dm, the supply of mass dms and of the Guidelines.

Obviously not all of the supplied mass can be drained off below P. What happens with the extra mass given by dms dm ? It must be taken into account that above Ρ a back-pressure zone is gradually building up. (Before the front reaches Ρ, λ of the avalanching must be of the order of one.) This will slow down the speed and increase d, and finally a part of the mass will remain above P. If the avalanche is longer than is assumed here, the extra mass could be considerably larger and will be deposited above the mass at rest.

In Figure 3 it can furthermore be seen that the mean deposition depth, dmG, is indeed too large: the supplied mass cannot fill up the required deposition!

Finally in Figure 4 an example is given of an observed avalanche (Samedan/Ariefa on 2 January 1951). The plot of υ2 versus x shows, with calculation according to (14), a surprisingly large gradient ∂υ2 /∂x after the mass of length Δ has passed. The deceleration is much stronger compared to that of (15). This is an effect of the increasing mass which increases the flow resistance gradually, in contrast to (15) which considers only a constant front mass. The sharp change of the gradient after passage of the distance Δ will cause a large increase of Δd in the front part and therefore a steep deposition front. This is in accordance with observations. Velocity measurements of Gubler and others (1986) also show steep gradients, ∂υ/∂x, in the runout zone (e.g. Mader Grond avalanche on 17 January 1985), but it was impossible to determine the exact position of this deceleration.

Fig.4 . Distribution of υ2 over the runout zone.

The distribution of the pressure ρ = ρv2 on an obstacle in the runout zone is important for the elaboration of avalanche-danger maps, because this is, in addition to the return period, a criterion for the degree of danger. In the Guidelines (1990) a linear decrease of υ2 , and therefore also of p, is assumed. With this, one is in any case on the safe side.

The observed runout distance of the Samedan/Ariefa avalanche was 860 m. On the basis of climatological data and a guess of additional local wind influence, a mean fracture depth d0 = 1.00 m in the starting zone was assumed. Equation (16) delivers a runout distance of 844 m, whereas Equation (14) gives a somewhat too large value of 1031 m. However, if a slightly less pessimistic wind influence is assumed, we can just assume d0 = 0.8 m. In this case equation (16) delivers xsG = 720m and Equation (14) 807 m! This demonstrates that the runout distance is very sensitive to fracture depth, a quantity which is very difficult to determine locally. Unfortunately so far no accurate measurements on the whole fracture area (e.g. by photogrammetry) before and after an avalanche event have been made.

Conclusions

A rectangular velocity profile can be justified, because shearing is concentrated in the bottom layer. In addition to dry friction, a flow resistance proportional to the square of speed must be taken into account, because of the plastic behaviour of the snow clods and the uneven ground.

The recommendation of the Guidelines for a transition zone of 0.7 g/(ξdu ), when the slope changes from ψ0 to ψu , can be maintained. If however a critical value, λ, of the snow is exceeded, a “normal” flow on ψu cannot be attained. The flow on ψu will continue, over a limited distance, corresponding to a speed according to ψ0 . This will usually occur for values of ψu close to the critical value of tanμ.

The new model for runout — taking into account an increasing mass and snow pressure due to λ — is in fairly good agreement with the calculation according to the Guidelines if a high value for λ is taken. For values of ψa close to the critical angle tan ψcr = μ, the runout distance is about 20 % larger in the new model. The main differences from the Guidelines are a much lower mean deposition depth and a much faster decrease of velocity. The instructions given in the Guidelines by Equations (16) and (17) can be maintained, although if real depths are needed, the proposed lower values should be applied. The velocity distribution, used for the pressure distribution in avalanche-hazard maps, could be replaced by a faster decrease than linearly with the square of speed.

References

Bagnold, R.A. 1954 Experiments on a gravity–free dispersion of large solid spheres in a Newtonian fluid under shear. Proc. R. Soc. London, Ser. A, 225, 4963.Google Scholar
Bagnold, R. Α. 1966 The shearing and dilatation of dry sand and the “singing” mechanism. Proc. R. Soc. London, Ser. A, 295, 219232.Google Scholar
Gubler, H.U. 1982 Strength of bonds between ice grains after short contact times. J. Glaciol., 28(100), 457473.Google Scholar
Gubler, H. Hiller, M. Klausegger, G. Suter, U. 1986 Messungen an Fliesslawinen. Eidg. Inst. Schnee– Lawinenforsch. Mitt. 41.Google Scholar
Roch, Α.. 1966 Les variations de la résistance de la neige. International Association of Scientific Hydrology Publication 69 (Symposium at Davos 1965 — Scientific Aspects of Snow and Ice Avalanches), 8699.Google Scholar
Salm, B. 1972 Grundlagen des Lawinenverbaues. Bündnerwald, Beiheft 9, 6781.Google Scholar
Salm, B. Unpublished a Das Geschwindigkeitsprofil in einer Fliesslawine Eidgenössisches Institut für Schnee–und Lawinenforschung Interner Bericht 574, 1979 Google Scholar
Salm, B. Unpublished b.Fliessübergänge und Auslaufstrecken von Lawinen Eidgenössisches Institut für Schnee– und Lawinenforschung Interner Bericht 566, 1979 Google Scholar
Salm, B. Burkard, A. Gubler, H. 1990 Berechnung von Fliesslawinen. Eidg. Inst. Schnee– Lawinenforsch. Mitt. 47.Google Scholar
Schaerer, P.A. Salway, A.A. 1980 Seismic and impact–pressure monitoring of flowing avalanches. J. Glaciol., 26(94), 179187.Google Scholar
Voellmy, A. 1955 Über die Zerstörungskraft von Lawinen. Schweiz Bauztg.73, 159165, 212217, 246249, 280285.Google Scholar
Figure 0

Fig.1 . Model for shearing near the ground.

Figure 1

Fig.2 . Flow transition for different values of λ.

Figure 2

Fig.3 . Mean deposition depth of the present calculation dm, the supply of mass dms and of the Guidelines.

Figure 3

Fig.4 . Distribution of υ2 over the runout zone.