INTRODUCTION

Strain and stress in snow are basic parameters for studying the behavior of a snow cover on a slope. From this standpoint, four methods of measuring deformation/pressure in snow have been developed to determine strain/stress, by our laboratory. All are based on an assumption that motion of a snow cover on a slope is 2-dimensional flow in a vertical plane along the maximum slope, if the contour lines of the slope are straight and parallel.

HOLE-MARK METHOD (Shimizu)

Internal strains of the snow cover on a slope are determined by this mechanical method (Shimizu and Huzioka 1975). The original instruments were targe and heavy, requiring at least three persons for handling; the latest version is compact and light, and measurement with a higher accuracy than before can be made by one person.

By the use of a wall-smoother and a ground-line fixed on a slope parallel to the contour line (Figure la), vertical walls along the maximum slope could easily be’ cut out from the snow cover at successive positions along the ground-line. Five fine straight holes, each 6 mm in diameter and 40 cm in length, were bored as a set in parallel to the ground-line in a homogeneous layer of the snow cover, using a 5-hole boring device (Figure lb).

The initial configuration of five holes, a square of 4 cm x 4 cm and its center, was photographed with a scale and a vertical pendulum. Then the wall was buried with snow. The final configuration of holes was photographed on a new wall advanced by 35 cm along the ground line from the initial wall, after an appropriate time interval. A new set of holes was bored in the final wall for a successive measurement.

Fig. 1. Instruments for Hole-mark method, a: wall-smoother, b; 5-hole boring device.

Although displacements of 3 points (holes) are necessary and sufficient for the calculation of homogeneous strain, the five holes were bored to check if homogeneous strain really took place or not. It was confirmed that strain of snow in a homogeneous layer could be well approximated by a finite homogeneous strain, especially for a uniform slope. Therefore, the principal axes of strain, the principal strains and their rates in a homogeneous layer were calculated.

SHORT-SPAN DEFORMATION GAUGE (Hirabayashi)

To measure the extension/contraction of snow in a small domain, preliminary measurements were made in winter 1984, using a newly designed electric deformation gauge. The gauge (Figure 2a) consists of a magnetic sensor (Hall IC) H fixed inside a cabinet A, a permanent magnet (alnico) M connected with a saw-tooth plate P₁ by a rod sliding through the cabinet, and another saw-tooth plate P₂ fixed to the outside of the cabinet A. Fixing the saw-tooth plates firmly in snow, extension/contraction of snow changes the distance between the Hall IC H and alnico M, resulting in change of the voltage output of the Hall effect sensor. As seen in Figure 2b, sensitivity of the gauge was about 4 x 10^-2 mm in the central region which corresponded to a strain of I x 10^-3 approximately. The inclination of the gauge was monitored by a built-in clinometer C.

Fig. 2. Short-span deformation gauge, a: the gauge; b: characteristics.

For setting the gauge, a snow block, approximately 20 cm x 20 cm x 60 cm, was taken out from a pit-wall in the snow cover to build a cavity, using a sepcially designed device. Then a gauge was set on an inner wall of the cavity depending upon the direction of measurement, removing a small amount of snow for the cabinet A of the gauge and thrusting the saw-tooth plates fully in the snow. Finally, the block was put back in its place, and the pit was buried with snow. The outputs of the gauge (Hall IC and clinometer) were recorded continuously.

After the experiments, it became clear that the cabinet A should be outside of the set of saw-tooth plates not to change mechanical conditions of snow between the plates.

LONG-SPAN DEFORMATION GAUGE (Akitaya)

To measure the local extension/contraction of a snow cover on a slope, this electrical gauge was designed and used in the field in winter, 1984. The gauge (Figure 3) consists of a linear potentiometer (2 kΩ/20 cm) C, and a measuring rod composed of 2 sliding pipes A and B with hooks (aluminium angle bar) D₁ and D₂ at both ends of the rod.

Fig. 3. Long-span deformation gauge.

Cutting out a long wall of a snow cover along the maximum slope, the gauge was fixed on the wall by thrusting the hooks D₁ and D₂ in the snow until the pipe A touched the snow wall. Because the working distance of the potentiometer C was 20 cm in length, initial length of the measuring rod was adjusted in a range of 2.3-2.5 m according to the stress condition of the snow cover.

Output of the potentiometer A was recorded continuously by a digital recorder. Apparent sensitivity of the measurement was 0.8 mm which corresponded to a strain of 3 x 10^-4 approximately, affected by the resolving power of the recorder.

SNOW PRESSURE GAUGE (Oh’izumi)

A thin-disc type of snow pressure gauge (18 cm in diameter, 0.6 cm in thickness and 258 g in weight: Figure 4a) was made to determine stresses in snow cover. The snow force working on the pressure plate (9 cm in diameter) was measured by 3 small size load cells (1.2 cm in diamater, 0.4 cm in height, 5 g in weight and 5 N in capacity for each). The gauge showed linear characteristics for the load. A fringe (4.5 cm in width and 0.6 cm in thickness) was provided outside of the pressure plate to eliminate the edge-effect of the gauge on the measurement. A micro-clinometer was set inside the fringe to monitor inclination of the gauge.

Fig. 4. Snow pressure gauge, a: the gauge; b: setting device.

To minimize the disturbance of snow condition, a sophisticated procedure was applied for setting the gauge. A thin snow plate (0.6 cm in thickness, 18 cm in width and 70 cm in length) was taken out from snow cover to be measured, making a thin cavity in the snow, by the use of a specially designed setting device. The gauge and the cord were placed in the snow plate fittingly as shown in Figure 4b, removing a part of the snow plate by the aid of a jig. Then the gauge was set in the thin cavity tightly by the setting device, together with the remaining original snow plate. The outputs of the gauge were recorded continously.

Two methods of stress determination from snow pressure are given separately (Oh’izumi and Huzioka 1985).

CONCLUSION

Four methods of measuring strain and pressure in snow are presented. The following were found. All work properly under normal conditions of snow. However, the hole-mark method does not allow a continuous measurement, and the short-span deformation gauge does not work for shearing deformation. Improvements of the two methods for these applications are necessary for the sophistication of research.