SU1596241A1 - Method of determining frost soil heaving - Google Patents

Abstract

The invention relates to the construction and can be used to study the heaving properties of freezing soils in the foundations of buildings. The purpose of the invention is to expand the information content of the method by determining the hydraulic component of the pressure of the puffy. A sample of fully saturated soil is placed in a container, at the bottom of which there is a layer of sand to supply moisture to the lower end of the sample. With the help of thermoelements, constant temperatures are set at the ends of the sample, and at the upper end, temperatures are set that correspond to the transition of the soil state from plastic-frozen to hard-cracked. After the temperature has stabilized, the ends of the sample are monitored for the movement of the meniscus in a capillary tube connected to the bottom of the container. The magnitude of the hydraulic component of the pulling pressure is determined by the force-measuring device at the moment when the inflow of moisture stops. 2 Il.

Description

The invention relates to construction and can be used to study the heaving properties of freezing soils in the foundations of structures,

The aim of the invention is to expand the information content of the method by determining the hydraulic component of the puff pressure

Fig. 1 shows an apparatus for carrying out the method; figure 2 -. graph of external water inflow density (I) in freezing soils and external load (P) versus zp -d-: (t).

The method is carried out as follows: m; i; m; m obozom.

Sample study soil i;

Fully saturated WATER by: .- :.

Claims (1)

In a solid upright parlor: olo hen} s container 2, naprp.: Er glass of ME glass, the inner walls of the cup are lubricated with vaseline. On eiO days -; -:. З:% о dats a layer of moisture-filled song. :: 3, which serves as the medium from which the year comes about, comes into industrial sample. 315 Thermoelements 4 are located between the sand layer and the sample and on the upper cold tjro end, impregnating constant temperatures to the sample rotores. The measurement of the amount of water entering the sample is carried out according to the speed of movement of the Meniscus 5 in a horizontally measured capillary tube 6 connected to the bottom of the container. The temperature on the cooling surface is set no higher than the critical value corresponding to p. 3 of the plastic-frozen soil to the solid-melt soil. This ensures that the entire temperature range is taken into account, in which the continuity of the hydraulic connection of the pore solution in the freezing soil sample is maintained, which is necessary obtaining maximum for this type of soil the value of the hydraulic pressure of the frosty heave. In the absence of experimental data, the critical temperature is allowed to be taken from regulatory sources (for example, SNIP P-18-7 6). After the temperature has stabilized, a certain freezing rate occurs at the ends of the sample, depending on the soil properties. As they freeze, they observe the movement of the meniscus in the capillary tube. With the appearance of a noticeable movement of the meniscus, I proceed to measuring the pressure of the heel by the method of its mechanical compensation. To do this, a force device, such as a spring dynamometer 8, is applied to the upper end of the sample with a screw 7, the intrinsic deformation of which is sufficiently small compared to the deformation of the soil strap. When the sample continues to freeze, quantities that compensate for the pressure of water that hydrates water in the thawed zone migrating in the freezing zone in the sand and the capillary tube . The intake of water is stopped and with further freezing of the sample, the pressure of growing crystals of diamonds leads to the outflow of a certain part of water from the sample, as indicated by the return motion of the meniscus 5 in the capillary tube. Observing the course of water absorption into the sample allows us to determine from the force-measuring device 2 the true pressure of the hydraulic frost crest of the soil. On the graph of the dependence of the density of external inflow of water (I) to freezing soils and external load (P) on time (t) (Fig, 2), two areas are clearly distinguished: I - the area of the hydraulic (migration) pressure of the frost crest (from tenths of before. The first units of Sha); II - area of crystallization pressure (up to tens and first hundreds MPa); P, and the parameters of the process of swelling, characteristic of heaving soils (silty sandy loam, loam, kaolin clay); the same for low-lumpy soils (montmorillonite clays); The same for non-rocky soils (sand, gravel). Accounting for the hydraulic pressure of the frost heave in engineering calculations allows for a more rational design and construction of linear structures and buildings with lightly loaded foundations. The method for determining the pressure of the frost heel of the soil, including placing the sample in a container, unilaterally freezing it from the bottom with moisture inflow and measuring the pressure of the heel in a force-measuring device, characterized in that it supports At the upper end of the sample, the temperature corresponds to the transition of the soil to the solid-frozen state, and the inflow of moisture into the soil is recorded, and and the value of the hydraulic pressure heave component take its values at the time of stopping the inflow of moisture in the ground,