RU2724192C2 - Loose material platform with loose air control - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: internal volume (10) of each vibration module by means of piping (14) communicates with source of clean air or any gas (19). Each vibration module of the following after the first rows of the vibration chamber is equipped with a device for countering compression (46), equipped with a plate against compression (47), placed above casing (44) of the electric vibrator, fixed on two combs (48) and (49), resting on fixed elements (39) on each side of vibration module.

EFFECT: this design of vibration modules ensures their dust protection and efficient unloading of any loose soldering material from any types of containers transported by any method, without manual or mechanized assistance.

15 cl, 15 dwg

Description

The present invention relates to a vibrating deck (vibrating deck) intended for unloading all types of granular and powdery products, including bulk materials that are subject to caking, from all types of containers, silos, tanks, tanks, freight vehicles and bunkers. Protection against dust penetration into vibration modules is provided.

Vibronastil includes one or more modules of vibration shakers mounted on an inclined pallet of a granular or powder product container. Vibronastil is intended for the final release of the container from the contents, i.e. - from the remnants of material not unloaded by gravity.

The vibration shaker module is a steel frame with cross members between which filler material is placed. On the cross members of the frame are placed compression springs carrying a metal sheet, on which a vibrator acts through at least one electric motor, and a sealing membrane is located on the periphery. Under the mass of the product filling the tank, the metal sheet compresses the springs and lowers, relying on the filler material. During unloading, the springs gradually expand until they are completely emptied, after which the sheet of metal rises and rests on the open springs. During this process, a rarefaction occurs inside the vibration module, compensated by the volume of air or gas penetrating between the metal sheet, the filler material and the bottom of the frame.

The air drawn in this way is saturated with dust at the base of the hopper. Dust gradually fills the space between the sheet of metal, the filler material and the base of the frame until it begins to impede the compression of the springs and the operation of the vibration shakers. Vibronastil completely loses its working capacity. The accumulation of dust between the metal sheet and the aggregate material can cause the sealing membrane to rupture, resulting in failure of the shakers.

Moreover, some bulk materials subject to intense caking, such as soy products, highly hydrophilic materials, such as potassium, can harden in containers. The pressure exerted by the caked mass, in particular in the area of the casing of the vibrator operating from the electric motor, as a rule prevents the unloading of materials of this type with the help of currently available vibro-pallets.

The present invention relates to a vibrating deck, which takes into account the disadvantages of the prior art vibro-flooring, in particular in terms of ensuring that the vibro-scraper module is filled only with clean air during loading and unloading cycles due to the supply of a source of clean air or other gas, such as nitrogen, to the inner volume of the vibro-shaker. .

The invention also aims to ensure the complete discharge of all types of granular and powder products, including highly cohesive materials.

For this, the vibration shaker module under consideration is equipped with a tube located next to it and an external tube placed in the conduit, through which electrical wiring is connected to the vibrator driven by an electric motor. The connection between the two tubes is made inside the shaker module by means of a fitting having at least one free hole. In addition, the outer tube and electric cable exit the container through the bottom of the container, or through the wall of the container, and enter a sealed box, or lie outside the container.

The sealed box is preferably provided with an air filter, or a nozzle open to the external atmosphere. Thus, the internal volume of the shaker module communicates with the volume of clean air through the hole in the fitting between the tubes, then through the external tube and the airtight box, or from the external environment of the container.

In another embodiment of the technical solution of the invention, the internal volume of the vibration module is connected to the box communicating with the volume of clean air, or to the external atmosphere of the container, by a tube inside which the electric cable does not pass.

An embodiment of the invention is possible, in which an essential feature is a box communicating with a source of partial or full supply of any gas.

Another essential feature of the invention may be a box connected to a volume of air or to a source of another gas, from where air or gas is supplied to the box under a pressure exceeding the pressure inside the vibration modules.

If the vibro-floor is made of a plurality of vibration modules, these modules are placed in one or more rows along the slope, making up one or more sections perpendicular to the slope. The intervals between the sections of the modules can have a different width, for example, to accommodate cable channels in them for supplying power to electric motors that drive the vibrators.

In one of the implementations, it is provided that the vibration modules are arranged in a circle in one or more tiers around a central discharge opening. With this arrangement, the gaps between the vibration modules can be located radially.

Many vibration modules comprise vibrating surfaces, while the gaps between the modules form fixed, non-vibrating sections.

When vibro-flooring is intended for unloading of non-cohesive bulk materials, the residual pile after unloading by gravity has a triangular shape, while vibro-flooring can begin to clean the slope of residues according to any of the scenarios.

When unloading cohesive materials, such as soy products, sawdust, potassium, and the like, loose, a single vibrating floor can not independently begin to clean the compressed residues.

In arrangements with a single vibration module, one row of vibration modules, or one circular tier of vibration modules, one or more deflectors are placed near the discharge opening, thereby limiting the load of contents on the cover of the electric vibrator located at the bottom of the module. Thanks to this, cleaning of the residual pile is possible.

The task is complicated in configurations with several rows or several circular tiers of modules, when the turn comes to cleaning the second module, second row or second circular tier of the modules. The caked product actually forms a block, the mass of which, acting on the protective casing of the electric vibrator, prevents the continuation of the cleaning of the remaining cargo. The unloading process is interrupted, requiring the use of alternative manual or mechanized material handling equipment, which is an additional source of increased risk for staff.

One of the essential features of the invention is represented by two ridges on the fixed elements of vibro-flooring, on which a plate against compression is mounted.

The specified anti-compression plate is a component of the anti-compression device and is mounted mainly over the casing of the electric vibrator, protecting it from direct compression by the mass of the load.

Another essential feature of the invention are ridges protivosdavlivayuschuyu bearing plate, which can have a triangular shape in vertical and horizontal directions and serve to p y sheniya matted mass cohesive material which impedes their course the product of the vibrating metal sheet. These ridges can have a profile of any configuration, for example, in the form of two sides of a triangle, or in the form of a gear profile, or another.

Other features of vibronic in accordance with the invention will also be discussed in the description below with illustrative non-limiting examples of implementation with reference to the accompanying figures, where:

- figure 1 shows a view in longitudinal section of a shaker under load;

- figure 2 shows the same vibration shaker module without load;

- figure 3 shows the module shaker in a spatial exploded view;

- figure 4 is given a detail of figure 3;

- figure 5 shows a perspective view of a variant of vibronic;

- figure 6 shows a perspective view of another variant of vibronic;

- figure 7 shows a view of the gap between the modules in section along the line I - I in figure 6;

- figure 8 is a view of vibronastil loaded with bulk material, in longitudinal section along the line II - II in figure 6;

- figure 9 is a view of a longitudinal section along the line II - II in figure 6 of vibronic flooring under the load of bulk product after cleaning the lower modules;

- figure 10 shows a perspective view of an anti-compression device;

- figure 11 shows a [isometric] view of the lower and upper ridges of the anti-compression device in section along the line II - II of figure 10;

- figure 12 shows a variant of the [isometric] view of the lower and upper ridges of the anti-compression device in section along the line II - II of figure 10;

- figure 13 shows a special profile of the ridge;

- figure 14 shows a perspective view of a hopper with one section of modules [vibration shakers];

- figure 15 shows a special anti-compression device.

Figure 1 illustrates the vibration shaker module 1, made on a frame 2, having transverse crossbars 3, on which springs 4 are fixed, and the space between which is filled with filler material 5. The metal sheet 6 is supported by a stiffener 7, and the vibrator driven by an electric motor 8 is supported by a frame 2 through springs 4. The peripheral membrane 9 along the perimeter of the sheet of metal 6 provides a connection between it and the frame 2. In figure 1, the vibration module is shown in the loaded position. In figure 2, the same vibration module is shown without load with the formation in its internal volume of a layer of air 10 that penetrates during unloading.

The figure 3 shows the module 1 installed in the container 11, for example, in a hopper, with a sloping bottom 12. Through the inner tube 13 and the outer tube 14 held cable 15 of the vibrator 8 driven by an electric motor (not shown). The figure 4 shows that the inner tube 13 through the coupling 16 communicates with the outer tube 14, which is attached to the same sleeve 16 using a cable gland 17. The coupling 16 has at least one free hole 18, which provides communication of the internal volume 10 of the module 1 with the internal volume of the outer tube 14, which in turn communicates with the volume of clean air 19, as shown in figure 3. The diameter of the tube 14 exceeds the diameter of the cable 15, which provides sufficient airflow inside it. Figure 3 shows that outside the container 11, for example, in the channel 20 below it, the box 21 contains the volume of clean air 19, while the tube 14 and the cable 15 are connected to the box 21 through the cable gland 22. The cable 15 exits the box 21 through cable gland 23 and is included in the second, electrical terminal box 24.

In another embodiment, also shown in figure 3, the outer tube 14 is attached to the wall of the module 1 through a cable gland 25 and is connected in the same way with the volume of clean air 19 in the box 21 in the absence of a passing cable 15.

Box 21 includes an air filter 26 of any known design, cylindrical, rectangular or other shape, or a pipe 27 connecting the internal volume of the box 21 with another volume of clean air 19 or most often with the external atmosphere of the container 11. Alternatively, the tube 27 can be connected with a source of partial or complete supply of any gas. Several boxes 21 can be interconnected by a tube 28.

Figure 5 shows a particular embodiment of the constructive solution, in which the protective tubes 14 and cables 15 are laid through the wall 29. The wall 29 separates the internal space of the tank 11 from the volume of clean air 19, in this case, from the external atmosphere 19, with which the tubes 14 directly communicate . The cables 15 then directly go to the electrical cabinet 30.

Thus, the inner space of the vibration modules 1 communicates with the volume of clean air, filtered air or any gas.

Figure 6 shows a hopper 11 with walls 29 and an inclined bottom 12, along which sections 34 and 35 of vibration shaker modules 1 are placed side by side, of which three modules 31, 32 and 33 constitute section 34. The section may include any number of vibration shaker modules without restriction the scope of this invention. The interval 36 between sections 34 and 35, detailed in FIG. 7, can be used as a cable channel 37, covered by a cover 38 with a profile in the form of the sides of a triangle 39. The cable channel 37 with a cover 38 forms a fixed, non-vibrating, structural element, inside which pass protective tubes 14 and cables 15. The surface formed by the combination of vibration modules 1 and the gaps 36 between them, is vibroplast 40.

The figure 8 shows the discharge gap 41 at the base of the slope 12. The hopper 11 is filled with a loose cohesive product 42, which lost the ability to gravity discharge. The canopy with an opposite inclination 43 over the cover 44 of the electric vibrator 8 of the lower vibration module 31 creates a free space 45 around the electric vibrator 8, which allows the electric vibrator 8 of the vibration module 31 to overcome the adhesion of the product.

Figure 9 illustrates the possible order of operations performed by the vibration modules 32 and 33 when unloading the compressed bulk material after emptying the module 31. Without special preliminary measures, the electric vibrator 8 of the vibration module 32, which is under very high pressure, cannot independently destroy the compressed pile. The figure 9 shows the anti-compression device 46 of the vibration modules 32 and 33.

Figure 10 shows in more detail the anti-compression device 46, including an anti-compression plate 47 held above the casing 44 of the electric vibrator 8 (not shown) with two ridges, the lower 48 and the upper 49. The minimum distance between the anti-compression plate 47 and the top of the casing 44 is about 5 see, which is not a limiting parameter under this invention. Plate against compression 47 protects the casing of the vibrator 8, driven by an electric motor, from direct pressure of the load. The vibrator 8 driven by the electric motor, free of this from being squeezed by the mass of the product 42, as shown in figure 9, can vibrate and bring down the pile of the product 42.

The lower ridge 48 contains a rod 50 of any preferably circular cross section, on which a triangular profile 51 can be rigidly fixed along its entire length or on some segments of its length so that the axis of symmetry of this profile 51 extends vertically and the apex of the triangle points up . Profile 51 is designed to destroy lumps of material falling on the anti-pressure device 46.

The upper ridge 49 includes a rod 50 and, optionally, the same vertically arranged triangular profile 51, to which segments 52 of the triangular profile can be added with an axis parallel to the slope 12 and a vertex pointing to the top of the slope, as shown in figure 11. Segments 52 are intended for crushing lumps of material rolling downhill so that such lumps cannot interfere with the flow of the product.

Plate against compression 47 is fixed in the upper part and on the peaks of the described two ridges 48 and 49.

The anti-compression plate 47 may be placed horizontally, as shown in figure 11, or parallel to the inclination line 12, as shown in figure 12.

As shown in figure 10, the deflector 53 can be placed above the plate against compression 47, to reduce pressure on it and, therefore, on the anti-compression device 46. Each of the ends of the rod 50 is mounted on a support plate 54, which has a vertical part 55 and an inclined gear part 56. The inclined part 56 is fastened with screws or bolts, or in another way, to the slope 39 of the cover 38 of the cable channel 37. The vertical part 55 of the support strip 54 is bolted or in any other way with the same vertical part 55 of the adjacent anti-compression device.

The figure 13 shows the ridges 48 and 49, the rods 50 of which have a profile [link] of the chain in a vertical plane, providing special strength under vertical loads.

The figure 14 shows an example of a single-section vibronastil. In this case, the support bar can consist only of a vertical part 55, which is attached to the wall 29 of the hopper 11.

In variants with multiple sections, all adjacent vertical parts 55 of the support strips 54 are interconnected by bolt or any other type of fastening. The vertical parts 55 of the extreme support strips are attached to the walls 29 of the hopper 11.

In the embodiment of the design solution in FIG. 15, where the interval 36 between the sections is narrowed, the support strip 54 is reduced to one vertical plate 55 resting on the inclined bottom 12 of the container 11, while the adjacent plates 55 are interconnected by bolt or any other type of fastening. In this case, the plates 55 are provided with a bar with an eye 57 for anchoring them on the slope of the bottom 12 using anchors 58.

Of course, the invention is not limited solely to the described and illustrated particular structural solutions; on the contrary, it covers all options. In particular, it is clear that any container for granular and powder material is meant: a silo, a drive, a railroad car, a container, a hopper, etc., and that a rectangular or round shape of the storage tank is not exceptional, and any other configuration is allowed, for example, polygonal, hemispherical dome-shaped, with one or more passages, with one or more gaps, etc.

Thanks to the use of the anti-pressure system claimed in the invention, vibro-flooring allows you to remove all bulk materials with all possible configurations of vibro-flooring without the additional use of manual or mechanized means, completely eliminating the danger to staff. In addition, this new type of vibration flooring includes modules that are not susceptible to dust accumulation for a long time, which ensures reliability and durability in operation and maintenance.

Claims (15)

1. Vibro-flooring for placement in a container (11), comprising at least one vibro-shaker module (1), wherein each vibro-shaker module is equipped with at least one vibrator (8) driven by an electric motor mounted on a metal sheet (6), which relies on aggregate material (5) when vibro-floor is under load, and which rests on compression springs (4) when vibro-floor is not loaded, characterized in that the increase in internal volume (10) of each vibro-shaker module during the emptying cycle is compensated by an external tubes (14) for supplying clean air (19) or another gas without forcing from the atmosphere surrounding the container, while the outer tube (14) is made with the possibility of opening into the atmosphere and connects the internal volume (10) of the module with the volume of clean air (19) or other gas outside the tank (11). 2. Vibrating on p. 1, characterized in that the outer tube (14) serves as a protective sleeve for passing through the inside of the power cable (15) of the vibrator driven by an electric motor. 3. Vibronastil according to claim 1 or 2, characterized in that the volume of clean air is contained in the box (21). 4. Vibronastil according to claim 3, characterized in that several boxes (21) are interconnected by a tube (28). 5. Vibro-flooring according to claim 1, characterized in that the volume of clean air is the atmosphere outside the container. 6. Vibrating on p. 3, characterized in that the box is equipped with an air filter (26). 7. Vibrating on p. 1, characterized in that at least one vibration module is equipped with an anti-compression device (46), including an anti-compression plate (47) mounted on the ridges (48) and (49) above the casing (44) of the electrovibrator. 8. Vibro-flooring according to claim 7, characterized in that the support strips (54), to which the ends of the ridges are attached, rest on fixed sections (36) on both sides of this module. 9. Vibro-flooring according to claim 7 or 8, characterized in that at least two support strips located on only one side of the crests include only vertical plates (55) held by anchors on the inclined bottom (12) of the container using plates with eyes (57), coupled with the vertical plates of the support strips, and anchors (58). 10. Vibro-flooring according to claim 7 or 8, characterized in that the support strips include a vertical part and a gear inclined part (56), attached to the ramp (39) of the cable channel cover (38) (37), while the vertical part of the support bar is attached bolts to the vertical part of the support bar of the adjacent anti-compression device. 11. Vibro-flooring according to claim 7 or 8, characterized in that at least two support strips located on one side of the ridges include a vertical part intended for attachment to the container wall (29). 12. Vibro-flooring according to claim 7 or 8, characterized in that the rods (50) have a predominantly circular cross-section and preferably carry triangular profiles (51) oriented vertically upward with their apex. 13. Vibro-flooring according to claim 7 or 8, characterized in that the upper ridge (49) can be provided with triangular segments (52), the axis of which runs parallel to the slope of the bottom, and the top is directed uphill. 14. Vibrating on p. 7 or 8, characterized in that the plate against compression is equipped with a deflector (53). 15. Vibronastil according to claim 7 or 8, characterized in that the rods carrying the ridges have a serrated profile in a vertical plane.

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