EXPERIMENTAL RESEARCH OF THE CLIFFS AND BANKS WASHAWAY

Vertical and inclined shores washout processes were simulated in the small-scaled water tunnel with curved bed and in the rectangular-sectioned hydraulic flume. Intensity of the washout of lithologically homogeneous material of vertical shore is in direct correlation with the attack angle of flow on the coast: Wa = 349.8(1 + + 3.21sin3 a), where Wa is the intensity of washout at the attack angle a. The power-low relation (Wb = 82 + 1.72b0.71) of underwater river bank washout intensity (Wb) from its incline (b) to the flow surface is fixed. Mathematic simulation results show that the ratio of side erosion to bottom erosion shifts to bottom erosion if flow velocity was increased. Due to their morphometric, timing and hydraulic parameters these models are closest to the processes parameters and morphology of the beds of slope drainage network of shallow waterflows. Sharp river bed curves, high flow velocities and flow turbulence on the top of high water are typical for them. All these features occur in the river drainage networks as well, especially on the mountainous rivers. On the plain rivers the most adequate are the high water processes analogues as long as high water passes in the berm edges of flood-plain coasts.

rill channel, scour, bed erosion, side erosion, angle of attack

1. Armand D.L. Reference of experimental methods in geomorphology // Probl. Fiz. Geogr. Vol. XIII. 1948. P. 37-58 (in Russ.).

2. Makkaveyev N.I., Khmeleva N.V., Zaitov I.R., Lebedeva N.V. Eksperimental'naya Geomorfologiya (Experimental geomorphology). M.: Izd-vo MGU (Publ.), 1961. 194 p.

3. Larionov G.A., Bushueva O.G., Dobrovol'skaya N.G., Kiryukhina Z.P., Krasnov S.F., Litvin L.F. Experimental research of water temperature and soils humidity influence on erosibility of model samples // Pochvovedenie. 2014. № 7. P. 890-896 (in Russ.).

4. Rozovskii I.L. Dvizhenie vody na povorote otkrytogo rusla (Water movement on the open channel turn). Kiev: Izd-vo AN USSR (Publ.), 1957. 188 p.

5. Chalov R.S. Ruslovedenie: teoriya, geografiya, praktika (Ruslovedenie: theory, geography. practice). Vol. 2. Morfodinamika rechnykh rusel (Morphodynamics of river channels). M.: KRASNAND (Publ.), 2011. 960 p.

6. Makkaveyev N.I. Hydraulic typification of erosional process, in Eroziya pochv i ruslovye protsessy (Soil erosion and channel processes). Iss. 3. M.: Izd-vo MGU (Publ.), 1973. P. 65-77.

7. Larionov G.A., Krasnov S.F. Statistically distributed model of soils and binder soils washing // Pochvovedenie. 2000. № 2. P. 235-242 (in Russ.).

8. Mirtskhulava Ts.E. Osnovy fiziki i mekhaniki erozii rusel (Basis of physics and mechanics of channel erosion). L.: Gidrometeoizdat (Publ.), 1988. 304 p.

9. Shvebs G.I. Formirovanie vodnoi erozii, stoka nanosov i ikh otsenka (Water erosion and sediment run-off formation, its evaluation). L.: Gidrometeoizdat (Publ.), 1988. 184 p.

10. Stok i ruslovye protsessy (Runoff and channel processes). M.: Izd-vo MGU (Publ.), 1971. 115 p.

11. Petukhova L.N., Rysin I.I. Horizontal channel deformations as a factor of fluvial relief forming in Udmurtia, in Problemy flyuvial'noi geomorfologii (Problems of fluvial geomorphology). Izhevsk: Nauchnaya kniga (Publ.), 2006. P. 183-187.

12. Nachtigale J., Poesen J., Sidorchuk A., and Torry D. Prediction of concentrated flow width in ephemeral gully channels // J. Hydrological processes. 2002. Vol. 16. P. 1935-1953.

13. Torry D., Poesen J., Borelli L., and Knapen A. Channel width - flow discharge relationships for rills and gullies // J. Geomorphology. 2006. Vol. 76. P. 273-279.