SU1066808A1 - Method of compacting a hard concrete mix - Google Patents

Abstract

1. METHOD OF SEALING A HARD CONCRETE MIXTURE, by applying the effect of vertical vibrations with increasing frequency and compressive load, characterized in that, in order to increase the efficiency of compaction and strength of the resulting products, the effect is effected by vertical vibrations with a frequency of 1015 Hz with a vibration acceleration of 50- 80 m / s, which is increased at a rate of 0.2-1.0 Gd / s for a time {t, 5-2.0.) HZh, and the pressing load is applied when the frequency reaches 20-50 Hz at an angle of 60-85 &;deg; to the surface of the mixture with a speed of movement of 0.01-0.1 m / s, and a pressure of 40-120 kPa. 2. The method according to claim 1, characterized by the fact that the pressure loading pressure is increased in the direction of movement. e. ..... .- ". . ..., in the, -. in f. . . .-. -. . l r - ::: ;;: v:; -; f.; V-:; -:; , -;. :: ..:;, -; ..; ...-; - ..:;: -. ....:;. “V,. .% ...,:, -. g. Vor I Vat 1 f phi9.

Description

The invention relates to the building materials industry in the manufacture of products from concrete and reinforced concrete and may find application in the rigid compaction of vibratory concrete.

In the process of vibrocompaction, the properties of the concrete mix change, therefore, working processes with variable vibration parameters are most effective.

A known method of compacting a concrete mix is carried out first in shock mode with a frequency of 1.5-8.1 Hz with a table elevation height of 12 mm, and then with an increased frequency of 10.5-; 58 Hz and an amplitude of 0.2-1 , 4 mm CllT.

There is also known a method involving simultaneous exposure of a concrete mixture to vertical vibration and vertical impact with a frequency of 47-50 and 3.37, 5 Hz 1:21, respectively.

The disadvantage of these methods is the need to use devices with two drives for their implementation. In addition, the action of one vertical vibration does not provide a uniform structure of concrete in density.

Closest to the invention is a method of compacting a rigid concrete mixture by applying the effect of vertical vibrations with increasing frequency and pressing load of the NWT,

A known method of forming articles involves filling the mold with a material on which the presser cover is placed on top. Then the mold with the material is vibrated at the optimum frequency, and an additional sealing load is applied to the cap. Subsequently, the form is subjected to repeated vibration with a frequency several times higher than the frequency of the first stage. However, the effect of the vertical load from the cover on the entire surface of the material during the entire period of compaction, as well as the absence of shear displacements of the upper layer, reduce the efficiency of the working process.

It has been established that the efficiency of the process of compacting rigid concrete mixtures is determined by the magnitude of the stresses arising in the mixture. The magnitude and rate of occurrence of this stress depends on the intensity and direction of the vibration, the masses of the overlying layers and the ground dynamic pressure, which should be applied to the surface of the mixture at a certain angle.

The purpose of the invention is to increase the sealing efficiency and strength of the resulting products.

This goal is achieved by the fact that according to the method of compacting concrete mix by applying the influence of vertical vibrations with increasing frequency and pressing load, the impact is carried out by vertical vibrations with a frequency of 10-15 Hz with a vibration acceleration of 50-80 m / s, which increases with a speed of 0 , 21, 0 Hz / s for a period of time (1.52, 0). The same, and a pressurized load is applied when a frequency of 20-50 Hz is reached at an angle of 60-85 ° to the mixture surface with a displacement rate of 0.01-0. 1 m / s and a pressure of 40-120 kPa.

In this case, the pressure of the pressing load is increased in the direction of movement.

FIG. 1 shows a scheme for monitoring the method; in fig. 2 is a diagram of the stresses arising in the mixture along the height of the layer.

Concrete mixture 1 is placed in form 2, vibrated with variable vibration parameters, then it is subjected to dynamic loading 3 of local action at an angle moving with speed & V. The voltage from the mass of the mixture is characterized by direct I, from the applied over dynamic load - curve III. The resulting voltages are characterized by curve IV.

Thus, the effect of low frequency in the initial stage of the process without loading pressure provides a significant rate of deformation of the mixture with air release, and the subsequent continuous increase in frequency and upper application with a shift of loading dynamic pressure with varying parameters leads to an intensive liquefaction of the mixture alignment of the stress state and the formation of a uniform in density structure of concrete with good quality front surfaces and calibration eaten in thickness.

Example 1. A concrete mix is prepared with a hardness of C, a grade of concrete 300, Portland cement M 400. We take cement consumption c 355 kg / m and water B 160 l / m. The composition of concrete is cement: sand: crushed stone 1: 1.44: 3.86 with W / C 0.45.

The mixture is loaded into the form installed on the vibrating plate with

Claims (2)

1. SEALING METHOD RIGID CONCRETE MIX by applying vertical vibrations with increasing frequency and pressing load, characterized in that, in order to increase the compaction efficiency and strength of the obtained products, the effect is carried out by vertical vibrations with a frequency of 1015 Hz with vibration acceleration of 50-80 m / s ² , which increase at a speed of 0.2-1.0 Hz / s over a period of time (1.5-2.0.) Gf, and a pressing load is applied when the frequency reaches 20-50 Hz at an angle of 60-85 ° to the surface of the mixture at a speed its movement of 0.01-0.1 m / s, and the value of d Aviation 40-120 kPa. 2. -A method of pop. 1, distinguished by the fact that the pressure value of the pressing load is increased in the direction of movement.