The retaining dam

A 100 m long retaining dam made of approximately 26 000 m₃ earth-fill has been constructed. The dam stands 11 m above the original terrain and rises

15 m from top to bottom on the avalanche side. On top of the dam, a 6.5 m high and 0.3 m wide steel mast is instrumented with six strain gauges to measure deflections in the mast. Four gauges are mounted 2.4 m above the top of the dam for providing axial and moment stresses, and two 3.8 m above the top for providing moment stresses. The mast should withstand an equivalent uniformly distributed static load of 40 kPa.

In addition a 0.16 m diameter load cell is mounted at the northern end 1.0 m above the top of the dam. The load cell records both impact pressures and the time that snow passes the top of the dam.

The concrete structure

Above the dam, 230 m up the avalanche path, a 4.5 m high and 0.6 m wide concrete structure has been constructed. The impact pressures of the avalanches are measured by three load cells, each 0.6 m x 1.2 m. Because the load cells cover the whole front area, and the size of each cell at least is of the size of the snowmasses hitting them, the recorded pressures are considered to give realistic values for design purposes. The nominal full range of the sensors is 1000 kPa. On top of the structure a geophone vibration sensor is mounted with the sensitive axis aligned vertically.

The transmission tine conductors

At the same elevation as the concrete structure two 16 m steel masts have been installed, on either side of the avalanche path. Three 162 m transmission lines have been strung between the masts, 8, 12 and 16 m above the ground. Both ends of the cables are instrumented with a load cell. To prevent the effect of torque and shear forces, the load cells are mounted using tongue-and yoke-shackles as well as a rotation device. The full nominal range of the sensors is 227 kN tension.

The data recording system

The data are transmitted by armoured multipair cables to the recording instruments and placed in a hut 300 m south of the retaining dam. The maximum cable length is 700 m. The recording system consists of bridge DC-amplifiers with automatic null-balance and automatic adjustment of bridge excitation voltage using the remote sensing signals, and 5-pole lowpass filters to improve signal-to-noise ratio and to eliminate aliasing errors. Analog multiplexers multiplex 32-channels into a 2-channel system and a PCM-modulator which digitize the analog signals to 12-bit (4096 parts) accuracy, and put the digital signals on a serial bit-stream. A small magnetic tape-recorder is used to record the serial digital data.

Fig. 1. The experiment site and cross-section profile of dam, masts and concrete structure.

The sampling rate is 333.33 samples per sec. for each of the 32 premultiplexed channels. The filters are set to a cut-off of 75 Hz. Recorded data are read into a PRIME-750 computer and filed on a directed structure together with calibration data. Computation of engineering values, plotting of data, statistical work as well as Fourier transformations to check frequency distribution of signal energy are possible.

The sensor and recording system is protected against accumulation of static charges and high potentials from lightning using Faraday's cage principle, overvoltage protecting diodes and proper grounding.

Full symmetry for all measuring bridges was attempted, to eliminate thermoelectricl effects and resistance changes due to temperature changes and mechanical stresses.

Avalanche speeds

Up to May 1984 we have obtained speeds data from 6 avalanches in Ryggfonn, two of them from an earlier investigation before the construction of the dam (Tøndel 1977). Snow conditions varied from dry snow (25 February 1975) to wet snow in the whole path (23 April 1983) and also dry snow in the upper part of the path and wet snow in the rest. All avalanches except one had a common front for both the powdered snow and dense flow down to 700 m a.s.l. where there are simulataneous recordings on both the stucture and the transmission lines. Somewhere between this point and the stopping position, the powder snow overrides the dense flow; thus there is insufficient information about the avalanche velocity of the dense flow in the runout zone. For the sixth avalanche, there was a time difference between the powder snow and the dense flow of as much as 20 s at the concrete structure.

The relationship for the five analyzed avalanches between time used and horizontal distance travelled is shown in Figure 2. Maximum velocities vary between 38 m/s and 60 m./s (see also Bakkehøi and others 1983) and the runout distance for four of these varies by less than 100 m. The fifth avalanche passed the valley bottom by approximately 50 m.

The only equation used today for estimating avalanche velocities is the Voellmy-Perla equation (Voellmy 1955, Perla 1980), which is based on a friction parameter, μ, and a turbulence parameter called by Perla M/D. The time-distance relationship is computed for four sets of μ (0.2 and 0.3) and M/D (900 m and 450 m) by the method described by Bakkehai and others (1981); Figure 2.

The model, with only 2 parameters, does not provide a very good fit for the time taken, runout distance and maximum velocity. For some of the avalanches it can be explained that these parameters vary along the path because of variations in the snow conditions. The highest inaccuracies have been found in the runout zone, where the observed avalanches have a shorter runout distance and a more distinct retardation than the model indicates. Future analyses will be concentrated on a better physical understanding of what kinds of flow actually occur in avalanches. It may then be possible to benefit from previous experiments on such kinds of flow.

Fig. 2. The relationship between time and distance travelled for five avalanches, and computed values of Voellmy-Perla equation.

Recorded impact pressures on the concrete structure

Impact pressures have been recorded from four avalanches. Maximum pressures occurred in an avalanche of 23 April 1983. That avalanche consisted of wet snow; the velocity at the structure was 30 m/s, and the size of the avalanche was estimated to be 50 000 m₃. The density of the snowmasses was measured to 450 kg/m₃ and up to 650 kg/m₃ in the compacted snow in front of the dam. The masses passed the structure for a period of 50 sec. Figure 3 shows the snow profile around the structure before the avalanche was triggered, and the recorded maximum pressures; Figure 4 shows a selected part of the recordings.

The peak pressure, 541 kPa, was recorded on the upper load cell. Maximum pressure averaged over 15 sec. was 220 kPa. The time difference from the first signal to the peak value varied between 1.5 sec. (very small avalanche) to 15 sec. for the four analysed avalanches. In the literature the pressure, p, is usually estimated as ρ = k- ρ-v₂, with k varying from 0.5 for constructions submerged in the flow to 2.0 for peak pressures on small load cells. With an assumed density of ρ = 450 kg/m₃ and recorded front speed of v = 30 m/s, the back-calculated values for k are respectively 0.54 and 1.33. The ratio between peak and average pressures is 2.46, comparable with the ratio reported by Schaerer (1980) for load cells with an area of 0.645 dm₂.

The maximum recorded pressure on the lower, completely buried load cell was 83 kPa or 15% of the peak pressure on the upper load cell. The pressure on the lower load cell increased gradually with only small peak values, and the maximum pressure was recorded at almost the same time on all load cells (Figure 4). It is however still unclear whether impact pressure is an effect of flowing snow masses passing the load cell, or shear stresses transferred through the original snow cover.

Fig. 3. Snow surface before the avalanche and peak pressures on the concrete structure, 23 April 1983.

Fig. 4. Impact pressures on the concrete structure, 23 April 1983.

The output signal of the geophone on top of the concrete structure is very well correlated to the recorded impact pressure (Figure 5). There are no recordings of vibrations before the dense flow hits the structure, and the peak values occur at the same time for both sensors. The measurements indicate that geophones are suitable for detecting avalanches. The use of geophones is earlier described by Schearer (1980) for the measurements of avalanche velocities, and by Norem (1981) for warning of road-users by illuminating red lights when an avalanche has been detected.

Fig. 5. Correlation between the impact pressure on the upper load cell and the output signal of the geophone, 8 December 1983.

Recorded tension in the transmission line conductors

There are recordings on the transmission lines, 8, 12 and 16 m above ground from three avalanches. In addition, the avalanche on 10 January 1983 destroyed some strands on the two lowest lines.

The maximum values recorded so far are only 10% of the expected maximum values. The probable reason is that recordings are only from wet snow avalanches, with widths only about 30% of the maximum width,

Contrary to the load cells, the transmission lines recorded peak tensions a short time after the first impact (Figure 6). This effect is clearest for the lowest line, with the highest recorded tensions. Peak values for the three lines are respectively 1.3, 3.0 and 18.9 kN for the avalanche of 23 April 1983, and 3.0, 4.1 and 38.9 kN for the avalanche of 2 March 1984 (Figure 7). The preliminary results indicate that the energy is concentrated in the lower part of the powder snow.

Fig. 6. Tensions in the transmission lines, 23 April 1983.

From an engineering point of view, the energy distribution related to the height above the surface is important. Unfortunately the program for computing the equivalent static load and natural damping of initial loads is not yet ready, and it is impossible at this stage to compare the impact pressure on the structure and the transmission lines.

Fig. 7. Peak tensions in the transmission lines.