RU183943U1 - ROTARY-PULSATION MACHINE - Google Patents

Abstract

The utility model is used for dispersion, homogenization, and mechanochemical activation of composite materials in a liquid medium and for supplying the resulting mixtures and can be used in the production of monolithic heat-insulating cellular concrete with high performance properties for building envelope structures. The objective of the proposed model is to increase the efficiency of grinding, mechanochemical activation, hydration and homogenization of components of cementitious compositions, obtaining a homogeneous microporous structure of cellular concrete mixtures. A rotary-pulsating apparatus consists of a housing with inlet and outlet nozzles, inside of which a rotor and stator with protruding elements. The apparatus contains two stators and a rotor located between them with protruding elements towards the stators, while the rotor is made integral and consists of a part with protruding elements rigidly fixed to the shaft and a part in the form of trapezoidal inserts with protruding elements that extend from the plane of rotation of the rotor under the action of centrifugal inertia forces with the possibility of adjusting the gap between the protruding elements of the first and second stators and trapezoidal inserts, the rotation limit of which is carried out by the latch E inserts with protruding elements mounted in the slotted recesses fixed rigidly on the shaft portion, wherein the protruding elements are parts of the rotor slots in the projecting members of the first and second stators. The protruding elements may be elements in the form of perforated rings or teeth of a conical shape.

Description

The utility model is used for dispersion, homogenization, and mechanochemical activation of composite materials in a liquid medium and for supplying the resulting mixtures and can be used in the production of monolithic heat-insulating cellular concrete with high performance properties for building envelope structures.

Known rotor-pulsation apparatus, containing in the working chamber a rotor with input blades and output blades rigidly fixed on its disk, which are protrusions of the last row of the gear element of the rotor, and a stator rigidly fixed to the apparatus body, characterized in that the rotor is equipped with additional adjustable blades, mounted on the rotor disk with or without a hollow hub, having the ability to move between rigidly fixed blades (see patent No. 107965 IPC B01F 5/00, 2006). The disadvantage is that in the known rotary-pulsation apparatus, the clearance between the gear elements of the stator and rotor is not provided depending on the required grinding module.

Known rotary-pulsation apparatus containing a drive and a rotor and a stator installed in the housing, on the working surfaces of which are gear elements, which are rows concentrically arranged around the circumference, consisting of protrusions and depressions (see RF patent No. 2144935, MPK7 V01G 5/06 B01F 7/10, 1999). The disadvantage is that the known rotary pulsation apparatus does not provide the supply of finished products to the consumer and requires an additional pump.

Closest to the claimed model, by the totality of features, it is an adjustable rotor-pulsation apparatus comprising a housing inside which a stator and a rotor mounted on a shaft are concentrically placed with working bodies having annular perforated protrusions, characterized in that the rotor-pulsation apparatus is configured to adjusting technologically determined gaps between the rotor and the stator (see patent No. 92 361 IPC B01F 7/00, B01F 5/06, 2008). The disadvantage is that in the known rotary pulsation apparatus, the gap between the rotor and the stator is controlled by distance rings installed either in the place of stator fastening to the housing, or in the place of stop of the rotor when it is planted on the shaft, which causes great inconvenience associated with the need to disassemble the working camera apparatus when installing additional rings for the adjustment of gaps.

The objective of the utility model is to increase the efficiency of grinding, mechanochemical activation, hydration and homogenization of components of cementitious compositions, obtaining a homogeneous microporous structure of cellular concrete mixtures.

The technical result when using the proposed utility model is: obtaining highly dispersed cementitious compositions, controlling the structure formation of cellular mixtures at the stage of their mechanochemical activation, obtaining heat-insulating cellular concrete with desired operational properties.

The indicated technical results are achieved in that the rotor-pulsation apparatus, consisting of a housing with inlet and outlet nozzles, inside of which a rotor and a stator with protruding elements are coaxially mounted on the shaft in the working area, characterized in that the apparatus contains two stators and a rotor located between them with protruding elements in the direction of the stators, the rotor is made integral and consists of a part rigidly fixed to the shaft with protruding elements and a part in the form of trapezoidal inserts with protruding elements spools extending from the plane of rotation of the rotor under the action of centrifugal inertia forces with the possibility of adjusting the gap between the protruding elements of the first and second stators and trapezoidal inserts, the rotation of which is limited by the tabs of the inserts with protruding elements installed in cutouts with grooves of the part rigidly fixed to the shaft, and protruding the elements of the rotor parts are in the grooves of the protruding elements of the first and second stators. The protruding elements may be elements in the form of perforated rings or teeth of a conical shape.

When the rotor rotates at a speed of 1500 to 4500 rpm, there is a rapid alternation of alignment and non-alignment of the slots between the gear elements on the stator and the holes on the stator rings, which entails a synchronous change in the speed of the processed medium through the slots and holes, i.e. the appearance of a pulsating fluid flow at a high frequency. As a result, the medium being processed is exposed to high shear stresses arising in narrow radial gaps between rotating and stationary protruding elements due to significant velocity gradients, hydraulic shocks, cavitation, and small-scale pulsation in a wide frequency range. These factors, combined with intense mechanochemical influences in a liquid medium, significantly increase the speed of technological and chemical processes in liquid homogeneous and heterogeneous systems.

The maximum intensification of mass transfer, dissolution, hydration of binders and other similar processes is achieved in a developed turbulent flow under the influence of small-scale pulsation of the medium and processing of the material in microvolumes. All the energy supplied to the apparatus, with the exception of insignificant losses in the bearings and seal, is used to create high-momentum hydrodynamic flows and to process the material in a small vortex working chamber.

Moreover, the processing intensity, characterized by the volumetric power consumption in the working space of the apparatus, is 3-7 MW / m ³ , which is 2-4 times higher than in traditional capacitive devices with mixing devices.

Reducing the gap between the moving elements of the rotor inserts moving at a high speed and the stationary elements of the first stator contributes to the intensification of the processes of grinding and dispersion of the components of the cementitious compositions, and the area between the back of the rotor and the second stator contributes to the formation of a homogeneous microporous structure of the cellular concrete mixture.

In FIG. 1 shows a section 1 -1 of the RPA working chamber.

In FIG. 2 shows a general view of the rotor with inserts.

In FIG. 3 shows a section 2-2 of the lower part of the insert in place of its fixation on the rotor.

In FIG. 4 is a view A showing the boundary of the insert and the main rotor.

In FIG. 5 shows a general view of the first RPA stator.

In FIG. 6 shows a general view of the second RPA stator.

In FIG. 7 shows a fragment of a rotor without inserts.

In FIG. 8 shows a general view of the insert on the front side of the rotor.

In FIG. 9 shows a general view of the insert on the back of the rotor.

In FIG. 10 shows a General view of a rotary pulsation apparatus (RPA) and its working chamber.

In FIG. 11 shows a General view of a pilot industrial design RPA.

The rotor-pulsation apparatus (Fig. 1-11) contains two stators, the first 1 and second 2, with protruding elements, the rotor 3 with protruding elements in the direction of the stators 1 and 2. The rotor 3 is made integral and consists of part 4 with protruding elements, rigidly mounted on the shaft 5 and parts in the form of trapezoidal inserts 6 with protruding elements that extend from the plane of rotation of the rotor 3 under the action of centrifugal inertia with the ability to adjust the gap between the protruding elements of the first 1 and second 2 stators and trapezoidal inserts 6, the rotation limit of which is carried out by the clips 7 of the inserts 6 with protruding elements. The latches 7 of the trapezoidal inserts 6 are installed in the cutouts 8 with grooves in the part 4, which is rigidly fixed to the shaft. Moreover, the protruding elements of the rotor 3 components are included in the grooves of the protruding elements of the first 1 and second 2 stators. The intensive movement of the mixture through the apparatus and its supply to a certain distance is provided by the impeller 9 located in the housing 10. The rotor 3 and the impeller 9 are mounted on the shaft 5 and rigidly fixed on it with the help of dowels. The inserts 6 in the lower part are additionally fixed using the plate 11.

The processed mixture is fed into the working area through the inlet pipe 12 and leaves after the mechanochemical treatment in the pipe 13. To ensure sealing of the working area of the apparatus, the stuffing box seal is used 14. The rotary-pulsating device contains an electric motor 15 (Fig. 10) with an adjustable rotation speed from 1500 to 4500 rpm.

The proposed model works as follows. The cementitious composition in the form of a mixture is absorbed through the inlet 12 and enters the activation and dispersion zone between the rotor 3 and the first stator 1. To intensify the grinding processes and mechanochemical activation, the rotor 3 rotational speed varies from 1,500 to 4,500 rpm, which contributes to the deflection of the inserts 6 to achieve gaps between the protruding elements of the inserts of the rotor 6 and the first stator 1. Reducing the gap between the protruding elements of the rotor 3 and the first stator 1 contributes to the intensification of grinding and mechanical imicheskoy activation component binder composition. The mixture of the binder composition and the foam concentrate, passing through the gaps between the upper teeth of the rotor 3, falls into the zone between the back of the rotor 3 and the second stator 2, where foam is formed and the microporous structure of the cellular concrete is foamed.

Example. A pre-prepared mixture of composition: Portland cement - 300 kg, water - 150 kg (W / C = 0.5), protein foaming agent "Arecom-4" - 1 kg, was processed in a rotary pulsation apparatus with a rotor without movable inserts and in RPA with moving elements on the rotor for 1 to 3 minutes. The results presented in the table indicate the intensification of grinding and the increase in the specific surface of cement particles during processing in RPA with moving elements on the rotor to a greater extent than when processing the mixture in RPA with a conventional stator. In this case, the construction, technical and thermophysical properties of cellular concrete obtained using the inventive RPA significantly exceed the properties of cellular concrete obtained in RPA with a conventional rotor: the strength of cellular concrete increases by 4-15% depending on the processing time, and the thermal conductivity decreases due to the formation of a microporous uniform structure.

The technical result is achieved by the fact that the proposed model combines the adjustable functions specified in the task.

Claims (2)

1. A rotary-pulsation apparatus, consisting of a housing with inlet and outlet nozzles, inside of which a rotor and a stator with protruding elements are coaxially mounted on a shaft in the working area, characterized in that the apparatus contains two stators and a rotor located between them with protruding elements to the side stators, while the rotor is made integral and consists of parts with protruding elements rigidly fixed to the shaft and parts in the form of trapezoidal inserts with protruding elements that extend from the plane of rotation of the rotor along the action of centrifugal inertia forces with the possibility of adjusting the gap between the protruding elements of the first and second stators and trapezoidal inserts, the rotation of which is limited by the latches of the inserts with protruding elements installed in cutouts with grooves of the part rigidly fixed to the shaft, and the protruding elements of the rotor parts are in the grooves of the protruding elements first and second stators. 2. The rotary pulsation apparatus according to claim 1, characterized in that the protruding elements can be elements in the form of perforated rings or teeth of a conical shape.

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