RU199967U1 - VIBRATION BOTTOM SILO - Google Patents

Abstract

The utility model relates to vibration technology used in glass, construction, chemical, flour-grinding and other industries, and can be used in silos of bulk materials and in lines for the preparation of various multicomponent mixtures. The technical result is an increase in the efficiency of unloading bulk material from the silo. The vibrating bottom contains a conical funnel with a feed flange and an outlet. The angle of inclination of the funnel cone generatrix is 15-20 ° in relation to the horizontal plane. Fastening of the conical funnel to the flange of the silo discharge opening is carried out using suspension elements and vibration-insulating support washers. Sealing of the joint of the vibrating conical funnel with the flange of the silo discharge opening is achieved by a movable flange seal made in the form of a sleeve made of elastic material. The circular vibrations of the cone funnel are transmitted from an electric unbalance vibrator attached to it. To intensify the unloading process and prevent the formation of arches and stagnant zones of the unloading material, the inner surface of the conical funnel is equipped with three blade scrapers having an arcuate shape and spaced 120 ° apart from each other in relation to the center of the outlet. The direction of bending of the vane scrapers is opposite to the direction of circular vibrations of the conical funnel, which provides an additional vortex effect on the unloaded bulk material. The height of the paddle scrapers has a maximum value of 8-12 cm at the inlet flange and decreases linearly towards the outlet, where it is 2-3 cm. In the middle of the conical funnel, the height of the paddle scrapers is 4-6 cm. 4 silt.

Description

The utility model relates to vibration technology used in glass, construction, chemical, flour-grinding and other industries, and can be used in silos of bulk materials, as well as in lines for the preparation of various multicomponent mixtures.

Any production associated with the processing, storage, transportation and dosing of various bulk materials is usually associated with a large volume of technological operations for unloading these materials from silos and intermediate bins and feeding them into subsequent mechanisms and devices. At the same time, the integral elements of such operations are screw, gravity, rotary and vibrating feeders, aeration chutes, as well as vibrating bottoms and other devices and devices.

Since bulk materials are very diverse in their physical and mechanical characteristics (particle size distribution, moisture, density, tendency to bridging and caking, the ability to flow out of bunkers, etc.), for the smooth and continuous operation of technological lines for transporting raw materials, it is often required to intensify the processes of unloading materials from silos and storage bins. This is especially true for such clumping materials as soda, sulfate, saltpeter, chalk and other types of bulk raw materials that have high humidity. Unloading such materials from silos and bunkers can be accompanied by their hovering, the formation of arches and the formation of passive zones that prevent the effective outflow of raw materials from the bunker discharge openings. Therefore, to intensify the process of unloading such raw materials, unbalanced vibrators and pneumatic hammers installed on the walls of bunkers are used, as well as vibrating bottoms and vibrating funnels, which are the most effective mechanisms for stabilizing the outflow of bulk materials from bins and silos.

Known conical vibroactivator system Vibra Screw [1] for bulk materials. The device consists of an outlet movable structure with a vibrating cone, which is connected with a flexible joint to the lower fixed part of the unloading hopper. The vibration of this cone in the horizontal plane is generated by an unbalanced motor. At the same time, the guide cone transmits vibrational movements to the unloaded material and increases the intensity of its unloading. The disadvantage of this device is the large diameter of its discharge opening, which makes it difficult to attach standard feeding mechanisms to it without additional transition funnels, the feed openings of which do not exceed 400 × 400 mm.

It is also known a vibrating bottom [2, 3] containing a cone-shaped funnel, the cone of which has an angle of inclination of 55-60 ° with respect to the horizon. The cone-shaped funnel is fastened to the hopper discharge opening flange by means of ties and vibration-insulating gaskets, and the tightness of this joint is ensured by a flexible connecting sleeve. An inverse cone is installed inside the cone-shaped funnel, the base diameter of which is less than the diameter of the cone-shaped funnel base. At the same time, an annular gap is formed between the return cone and the funnel, through which, during the operation of the unbalanced vibrator attached to the funnel, the raw material is unloaded from the hopper or silo. The reverse cone reduces the pressure of the material on the feeder connected to the outlet of the cone-shaped funnel and prevents material from flowing out with an unwanted funnel forming in the center of the silo. However, the use of such vibrating bottoms, especially those having a relatively small (1-1.5 m) diameter, is inappropriate for unloading so-called problem materials. This is due to the fact that raw materials with high moisture content and a tendency to cake, poorly pass through the annular gap and form a roof and stagnant zones at the exit from the silo. It is also difficult to use such vibrating bottoms in the reconstruction of existing composite and mass gathering shops, since the large angle of inclination of the generatrix of the discharge chute requires additional installation height, which is often limited.

The closest technical solution to the claimed one is the construction of a vibrating bottom, which requires a lower assembly and construction height of the production facility [4]. Comparatively smaller dimensions in height of these vibration bottoms are associated with a smaller (15-20 °) angle of inclination of the cone generatrix of the cone-shaped funnel and the absence of an inverse cone. Such a constructive solution allows the integration of these devices into many existing batching and mixing lines, the supply overhead hoppers of which were not originally intended for mounting vibrating bottoms due to insufficient height between the hopper discharge flange and the assembly conveyor. The absence of a reverse cone in such a vibration chamber simplifies the design and facilitates the flow of clumping raw materials from small bins. With large diameters (5.5-7.5 m) of silos, vibrating bottoms with a diameter of about 2.5 m are required. The operation of such vibrating bottoms with a small angle of inclination (less than the angle of repose of the material) of the side walls of the vibrocone funnel is often associated with the formation of stagnant areas in near-wall zones of the silo, which is associated with the difficult movement of the unloaded material along the inner surface of the funnel. This is the main disadvantage of such mechanisms.

The problem to be solved is to increase the efficiency of unloading bulk materials from silos using vibrating bottoms that are not equipped with reverse cones and have smaller dimensions in height due to the smaller (15-20 °) angle of inclination of the side walls of vibrating cones.

This technical result is achieved by the fact that in the vibrating bottom of the silo, containing a cone-shaped funnel equipped with a loading flange and an outlet, the cone-forming of which has an angle of inclination of 15-20 ° with respect to the horizontal plane, the elements of the suspension of the cone-shaped funnel to the flange of the silo discharge opening, vibration-insulating support washers installed at the points of connection of suspension elements with the flange of the silo discharge opening and the loading flange of the cone-shaped funnel, a movable flange seal that ensures the tight coupling of the cone-shaped funnel with the silo discharge opening, as well as a drive in the form of an electric unbalance vibrator that creates circular vibrations of the cone-shaped funnel in the horizontal plane , the inner surface of the cone-shaped funnel, in contact with the bulk material discharged from the silo, is equipped with three radially located blade scrapers having an arcuate shape and spaced from each the other by 120 ° with respect to the center of the outlet, while the direction of bending of the vane scrapers is opposite to the direction of circular oscillations of the cone-shaped funnel, and the height of the vane scrapers, which has a maximum value of 8-12 cm at the inlet flange, decreases linearly towards the outlet and is 4 -6 cm in the middle of the cone-shaped funnel and 2-3 cm at the outlet.

The advantage of the proposed vibrating bottom for unloading bulk material from a silo in comparison with the prior art is that the inner surface of the cone-shaped funnel is equipped with three radially arranged arc-shaped scrapers. The presence of these scrapers makes it possible to effectively act on the unloaded raw material, which is located not only in the near-wall zones of the silo, but also over the entire area of the inner surface of the vibrating cone funnel, which makes circular vibrations.

Another advantage is that the arcuate shape of the scrapers, with general circular vibrations of the cone-shaped funnel, imparts additional circular displacements to the material to be discharged in the three internal sections of the vibrating bottom and thereby intensifies this process. And the variable height of the paddle scrapers provides a greater capture of material in the near-wall zones of the silo and a smaller one at the outlet of the conical funnel, where the material can be discharged without additional mechanical action. All this prevents the formation of arches.

The principle of operation of the device is illustrated by drawings, where in FIG. 1 shows a side view of a vibrating silo bottom; in FIG. 2 shows a top view of the inner surface of a conical funnel; in FIG. 3 shows a sweep of a blade scraper; in FIG. 4 shows the trajectories of material movement in the area of the blade scrapers.

The vibrating bottom of the silo contains: a cone-shaped funnel 1 (Fig. 1, 2), equipped with a loading flange 2 and an outlet 3; elements 4 of the suspension of the vibrating cone funnel to the flange 5 of the discharge opening 6 of the silo 7; vibration insulating support washers 8 made of elastic material, such as rubber; movable flange seal 9, made in the form of a sleeve; an electric unbalanced vibrator 10; blade scrapers 11, 12, 13 (Fig. 2, 3).

The vibrating bottom works as follows. When unloading bulk material from the silo 7, a gate (not shown) is opened, installed on the outlet 3 of the conical funnel 1, the loading flange 2 of which is attached by means of suspension elements 4 to the flange 5 of the discharge opening 6 of the silo. The tightness of the connection of the conical funnel with this hole is ensured by a movable flange seal 9 in the form of a sleeve. The flexibility of the connection of the suspension elements 4 with the flanges 2, 5 is achieved by vibration-insulating support washers 8 made of elastic material. These washers exclude the transmission of vibrations to the walls of the silo 7 when the electric unbalance vibrator 10 is turned on and concentrate them only on the conical funnel 1, which, in the process of intensifying the unloading of bulk material from the silo, makes circular vibrations. The frequency of these vibrations can reach 500 Hz with an amplitude of 10 mm.

Circular vibrations from the conical funnel are transmitted to the unloaded bulk material, and the presence of blade scrapers having an arcuate shape creates additional vortex trajectories of material movement. Moreover, the resulting vector 14 of the force acting on the bulk material from the blade scraper at different points of its arcuate shape (Fig. 4) is decomposed into components of the vector 15.16 directed both along the circumference of the conical funnel and towards its center (to the outlet) ... All this will undoubtedly activate the process of material outflow. In addition, the different heights of the paddle scrapers in different sections of the inner surface of the vibrating conical funnel contributes to an additional effect on different layers of material located in the unloading zone, which also reduces the likelihood of arches forming over the vibrating bottom.

Thus, equipping the vibrating bottom, the conical funnel of which has a relatively small angle of inclination of the generatrix of the cone, with arc-shaped blade scrapers makes it possible to intensify the process of unloading material from the silo.

Sources of information that you need to pay attention to during the examination:

1.G.A. Roginsky. Dosing of bulk materials. Moscow. Publishing house "Chemistry" 1978. 176 p.

2. Htps: // www vibrocom.ru Vibration intensifiers for the outflow of dry materials from bunkers.

3. Htps: // www studme.ru. Vibrating feeders - equipment for preparatory processes in plastics factories.

4. V.V. Efremenkov, V.V. Ruchkin. Vibration transport and technological mechanisms for the production of glass batch. Glass Russia. 2009 No. 6. S. 24-28.

Claims (1)

Vibration bottom of the silo, containing a cone-shaped funnel equipped with a loading flange and an outlet opening, the cone generatrix of which has an inclination angle of 15-20 ° with respect to the horizontal plane, suspension elements of the cone-shaped funnel to the silo discharge opening flange, vibration-insulating support washers installed at the joints of the suspension elements with the flange of the silo discharge opening and the loading flange of the cone-shaped funnel, a movable flange seal that ensures the tight coupling of the cone-shaped funnel with the silo discharge opening, as well as a drive in the form of an electric unbalanced vibrator that creates circular vibrations of the cone-shaped funnel in the horizontal plane, characterized in that the inner surface of the cone-shaped the funnel, in contact with the bulk material discharged from the silo, is equipped with three radially located blade scrapers, which have an arcuate shape and are 120 ° apart from each other in relation to to the center of the outlet, while the direction of bending of the vane scrapers is opposite to the direction of circular vibrations of the cone-shaped funnel, and the height of the vane scrapers, which has a maximum value of 8-12 cm at the inlet flange, decreases linearly towards the outlet and is 4-6 cm in the middle part a cone-shaped funnel and 2-3 cm at the outlet.

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