RU2318090C2 - Combined method for ground road bed dehumidification during road construction - Google Patents

Abstract

FIELD: road construction, particularly for ground preparation for further ground road bed forming, particularly to reduce humidity, in-situ road base and ground thawing and for fresh concrete hardening.

SUBSTANCE: method for ground road bed dehumidification involves uniformly removing moisture from ground by-passing water conversion from one state into another without water evaporation; decreasing process duration due to increased intensity of continuous moisture reduction. Ground is simultaneously subjected to continuous air flow from air side without ground excavation, to electromagnetic field with ultrahigh frequency to be provided with the use of waveguide path via antennas and to acoustic field having sound intensity of not less than 145 dB. The antennas are of slotted-guide type.

EFFECT: reduced specific power inputs for ground road base dehumidification and decreased time.

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Description

The invention relates to technologies for road construction works, in particular to the technology of preparing the soil for compaction during the construction of the roadbed, and can be used to reduce moisture, thaw road surfaces and soil at the place of its extraction, as well as to cure freshly laid concrete.

A known method of acoustic drying of capillary-porous materials (Patent RU 2062416, ⁶ F26B 5/02, publ. 06/20/96), in which drying is carried out with alternating intervals of acoustic exposure and pauses between them, while the size of the pause depends on the properties of the dried material.

This method can be used to reduce the soil moisture of the subgrade, however, given the fact that the maximum compaction of the soil during the construction of the subgrade is achieved by reducing its natural humidity to optimal [E.M. Dobrov et al. Clay soils of high humidity in road construction. M .: "Transport", 1992, pp. 3-5] by removing excess moisture from the entire volume of compacted soil to the required depth (up to 50 cm) without excavation, its use is not advisable, since it is possible to influence soil only from the side of the air, and acoustic drying proceeds most favorably with a material thickness of 3-6 cm [I. A. Rogov Physical methods of food processing. M., "Food Industry", 1974, p. 528], this is clearly not enough to reduce soil moisture to the required depth, in addition, when humidity decreases, its effectiveness drops sharply [ed. I.P. Golyamina Ultrasound. Little Encyclopedia. M., "Soviet Encyclopedia", 1979, p. 339], while the pause duration between the intervals of acoustic exposure should be large to ensure the replenishment of surface moisture from the deep layers and as the soil moisture decreases, it must be constantly increased. All this leads to an increase in the time of soil processing, to a decrease in the efficiency of the process, and given the heterogeneity and thermal characteristics of the soil, to poor-quality preparation for compaction.

A known method of combined drying of lumber [Patent RU 2101630, ⁶ F26B 3/347, publ. 01/10/98], based on alternating cyclical effects on the material by irradiation of microwave energy and blowing warm air. First, the material is exposed to warm air, surface moisture is removed, then microwave energy is supplied, which inertialessly heats the material to its entire thickness and causes an intense influx of moisture to the surface, at the last stage the material is intensively blown to evaporate water, thus preparing for the next intensive cycle exposure to microwave energy.

This method can be used to reduce the soil moisture of the subgrade, the use of microwave energy will allow the soil to warm to the required depth and provide an intensive flow of moisture to the surface, but the ability to act on the soil only from the air side, cyclic alternation of exposure to microwave energy and blowing with warm air , increase the duration of the process and thereby reduce its efficiency, and the removal of moisture from the soil surface in the form of steam requires large energy costs.

The closest in technical essence to the proposed method is a method of drying materials [Patent RU 2133934, ⁶ F26B 3/347, publ. 07.27.99], including the laying of the processed material in the working chamber with subsequent processing of it with flowing air and a microwave electromagnetic field supplied via a waveguide path connected to the working chamber through rectangular horn antennas. When using this method to reduce the soil moisture of the subgrade, it has the same disadvantages as the previous one, it is a large energy cost and low process efficiency.

The aim of the invention is to reduce the specific energy costs of the process of reducing soil moisture in the subgrade, increasing the efficiency of the process and reducing its duration.

The technical result from the use of the proposed method is to reduce specific energy costs while reducing soil moisture in the roadbed due to the uniform removal of moisture from the soil volume, bypassing the phase transition of water from one state of aggregation to another, without turning it into steam, in reducing the duration of the process for due to the greater intensity of continuous moisture removal.

This goal is achieved by the fact that in the combined method of reducing the soil moisture of the subgrade during road construction, the soil is exposed to flowing air and a microwave electromagnetic field supplied through the antenna through the waveguide path, while the soil is continuously processed from the side of the air without excavation and with simultaneous exposure to an acoustic field with a sound intensity level of at least 145 dB, and the antennas are slotted waveguide.

The proposed method consists in the simultaneous impact on the soil of flowing air, uniformly blowing the entire surface of the soil, acoustic waves and microwave energy, which have a directed effect on the soil surface from the side of the air.

The application of microwave energy provides volumetric heating of the soil, in which, due to the thermal expansion of the internal free and bound moisture, excessive pressure is created in the pores and capillaries even at soil temperatures below 100 ° C. Under the influence of excess pressure, moisture diffuses to the surface [Yu.V. Klokov Theory of moisture removal. “Storage and processing of agricultural raw materials”, No. 1, 2002, p. 7]. Selecting the range of microwave energy radiation, it is possible to ensure the drying of the soil to a large (required) depth. In addition to a sharp acceleration of the process of moisture exit to the surface, microwave energy automatically equalizes the moisture content of the material in volume, since areas with a higher humidity are more heated in the microwave field [I. A. Rogov Modern methods and equipment for microwave processing of food products in industry. M., 1971, p. 26].

Under the influence of the acoustic field from the side of the air on the soil, purely mechanical removal of moisture occurs, without the expense of energy for heating the soil and evaporation of moisture. This occurs due to the fragmentation of droplets and, as it were, “shaking out” of the liquid from the capillaries when strong acoustic flows arise at the surface. Small droplets are carried away by a strong air stream. Exposure to an acoustic field with a sound intensity of at least 145 dB dramatically accelerates the process of liquid evaporation from the surface, since acoustic flows appear on a wet surface, causing deformation of the diffusion boundary layer. In this case, the layer becomes thinner, the concentration gradient increases, which leads to an acceleration of the removal of moisture from the surface [Small Encyclopedia. Ultrasound. Ed. I.P. Golyamina. M., "Soviet Encyclopedia", 1979]. In this case, acoustic waves propagate in the soil under the influence of an acoustic wave, under the influence of which a decrease in the structural viscosity of the colloidal solution of water occurs [I. A. Rogov Physical methods of food processing. M., "Food Industry", 1974, p. 507], this facilitates the extrusion of water through capillaries to the surface of the soil during microwave heating.

The directed action of flowing air removes surface moisture in the form of steam and small drops.

Distinctive features of the proposed method compared to the prototype is that the impact on the soil is carried out without excavation from the side of the air environment, it is used continuously, the action of an acoustic wave with a sound intensity of at least 145 dB is additionally used, and the action of a microwave electromagnetic field is made through slot-wave antennas .

The proposed method is implemented as follows.

Flowing air is supplied to a certain site of soil from the side of the air without a recess, uniformly blows its entire surface, thereby removing moisture from the surface of the soil and taking it out of the area. Part of the flowing air is pre-branched and blown through aerodynamic transducers, where a directional acoustic wave is formed, which is sent to the soil surface. At the same time, the soil is exposed to microwave energy evenly distributed over the surface of the slot-wave antennas, which is achieved by the shape, location and number of radiating elements, determined to ensure coordinated supply, transmission of the maximum power level [V.A. Sosunov, A.A. Shibaev Saratov, directional couplers and their application. Volga Book Publishing House, 1967, pp. 87-107] and their best directed action [GBBelotserkovsky Fundamentals of Radio Engineering and Antennas. Part II, Antennas. M .: Soviet Radio, 1969, pp .98-202]. Microwave energy acts primarily on the moisture contained in the soil, while the released heat energy is spent on heating (expansion) and evaporation of the liquid directly inside the capillaries and pores, as well as on the formation of excessive pressure in them, which ensures intensive movement of moisture from the inner layers of the soil into the outer with the release of it on the surface in a drip-liquid state. As the moisture content of the surface layers of the soil decreases, its dielectric properties change, the depth of penetration of microwave energy increases [V.Ya. Yavchunovsky Microwave and combined drying: physical foundations, technologies and equipment. Ed. Saratov University, 1999, pp. 25-26], moisture is squeezed out from deeper layers of the soil. An acoustic wave acts on the soil, on its surface, where it accelerates the process of removing surface moisture by an air stream in a liquid state due to mechanical removal of moisture and the appearance of acoustic flows on a wet surface, on its subsurface layers, where the viscosity of a colloidal water solution decreases due to the propagation of acoustic vibrations , which facilitates its extrusion by capillaries to the soil surface by the influence of microwave energy.

Thus, a combined process of removing moisture from the soil occurs: microwave energy squeezes moisture to the surface, flowing air removes moisture from the surface, and an acoustic wave accelerates and removes moisture from the surface, and squeezes moisture to the surface. This allows the process to be carried out at lower temperatures, continuously, without local overheating of the surface soil layer, since when the humidity of the surface soil layer decreases, the influence of microwave energy and acoustic waves on it decreases, and increases on more humid layers. The process of removing moisture from the soil volume continues until the optimum moisture content is reached at the required depth (up to 50 cm), which ensures maximum soil compaction (for loams this is 15%). In the process of achieving soil moisture of the required level, the effect is transferred to the neighboring soil section of the subgrade prepared for compaction.

The essence of the proposed method is that the process of reducing soil moisture is carried out continuously from the side of the air without excavation and is the result of a combined simultaneous exposure to flowing air, an acoustic wave and evenly distributed microwave energy on the surface, in which it is possible to maximize the benefits of microwave energy on the soil, enhanced by the characteristics of the acoustic field, and at the same time ensure the removal of most of the moisture from the soil without phase transition of water s from one state of aggregation to another, without turning it into steam, i.e. without the cost of energy for vaporization. This increases the efficiency of reducing soil moisture, reduces energy costs and reduces the duration of the process.

The proposed combined method of reducing the soil moisture of the subgrade during road construction has all the signs of a continuous technological process and can be automated.

Experiments on the development of the proposed method were carried out on a specially designed device, structurally made in the form of a movable frame, on which elements are located that directly ensure the implementation of the process of reducing soil moisture in the roadbed: microwave generators, emitters, microwave energy transmission lines, acoustic transducers, a fan air pressure. The emitters are placed by the radiation plane parallel to the soil plane, above its surface, air space is provided between these planes to pass the necessary volume of air, which ensures moisture removal from the soil surface. The flowing air and the acoustic wave from acoustic transducers are supplied to the same space from an air pressure head fan. The microwave energy transmission lines are made on standard rectangular waveguides with geometric dimensions corresponding to the magnetron generation frequencies, the emitters are made on rectangular waveguides with transverse radiating slots, which are sealed with low-loss dielectric material.

When creating the device, mass-produced microwave generators based on M-137 magnetrons were used, complete with a power source and an electronic control circuit, a high-pressure fan of type VR6-13, and acoustic transducers of type U3G-4A.

Electrical and structural characteristics of the device: operating frequency of the microwave generator -460 ± 1% MHz; output power of the microwave generator - 50 kW; section of waveguides of the microwave energy transmission line - 457 × 228 mm; soil surface area covered by emitters - 3.5 m ² ; distance between soil surfaces and emitters - 0.1 m; acoustic power of one acoustic transducer 8 kW; acoustic transducer frequency - 45 kHz; number of acoustic transducers 3.

As a result of experimental studies, it was found that the use of the proposed combined method of reducing the soil moisture in the subgrade allows 30-60% moisture to be removed from the soil in a dropping-liquid state, without phase transition of water from one state of aggregation to another, without turning it into steam, which ensures 40% reduction in specific energy costs of the process.

Claims (1)

A combined method of reducing soil moisture in a roadbed during road construction, including treating the soil with running air and a microwave field using an electromagnetic field supplied via a waveguide path through the antenna, characterized in that the soil is treated continuously without excavation from the side of the air with simultaneous exposure to an acoustic field with the sound intensity level is not less than 145 dB, while the antennas are made of waveguide-slotted.