RU2062742C1 - Hopper for loose material - Google Patents

Abstract

FIELD: storage and dispensing of difficult-to-flow materials. SUBSTANCE: hopper for loose materials has bridge breaker with disks 3 secured with tilting on cylindrical support sleeve 4 enclosing shaft 2. Bridge breaker has vibration exciter with central helical gear 5 and unbalanced planet pinions 8 coming into meshing with gear 5. Planet pinion shafts 10 are connected with vibration exciter housing 11 through overrunning mechanism 6. Resilient members 12 and 13 are installed between vibration exciter housing 11 and central helical gear 5. Disks 3 execute complex motion: reciprocating-rotary motion and reciprocating axial motion are superimposed on rotary motion. Geometrical characteristics of trajectory of motion, dynamic range and direction of power action of disks 3 on material contribute to effective bridge breaking. EFFECT: enlarged operating capabilities. 1 dwg

Description

 The invention relates to devices for storage and subsequent issuance of bulk materials, prone to caking and arching, and can find application in various sectors of the economy.

Known bunker device for bulk materials, comprising a housing and a drive shaft mounted in its walls, equipped with a shredder made in the form of disks, on the surface of which there are curly tides [1]
However, such a bunker device provides a limited collapse zone.

Also known is a hopper containing a housing and a collapse mechanism, including a horizontal shaft with disks mounted on it with holes [2]
In this device, the loosening zone of the material is expanded. However, due to the fact that the shredder is installed near the wall of the body, its effect on the vault is of local importance.

The closest in technical essence and the achieved result to the proposed one is a hopper for bulk materials, comprising a housing and a mechanism for collapse, including a horizontal shaft with disks attached with holes on it, the disks being mounted on the shaft at an angle to its axis equal to or greater than the angle natural slope of the material, and adjacent discs are inclined towards one another. Disks on a shaft can be fixed eccentrically [3]
This technical solution of the hopper for bulk materials, compared with the above, is aimed at improving the efficiency of collapse. At the same time, as practice has shown, the circuit design features of the hopper shredder impose certain conditions on the course of the collapse of the bulk material and its unloading, and it is deeply dependent on the kinematics of movement of the shredder working elements, the physico-mechanical properties of the material being loaded, its fractional composition and state of aggregation.

 So, a demolition casing with disks inclined on the shaft relative to each other ensures satisfactory operation during unloading and storage of bulk materials in the hopper with unstable internal bonds between material particles. When recovering the flowability of a material under the influence of a shredder, material flows freely pass through funnel-shaped cavities in each group of adjacent disks without compaction and jamming of the material with its pouring from a cavity into a cavity through holes in the shredder disks. In this case, the unloading of the hopper is carried out uniformly with minimal energy consumption for inducing the material to expire.

 However, in the structurally constructive solution of the demolition mechanism, the positively dominant factor does not fully realize the shear nature of the movement of the working elements of the demolisher and, therefore, the geometric characteristics of the trajectory of movement, the dynamics and direction of the force of the inclined discs on materials that are prone to the formation of stable arches and freezing. This is especially true for materials that are prone to caking and increase viscosity with increasing humidity. The vast majority of moisture-containing materials are prone to freezing and corking.

 If there are separate large-sized inclusions in the bulk mass of bulk material, cases of their jamming between adjacent disks with subsequent pressing of the material and overgrowth of the bore at the level of their smallest angular closure under the influence of pressure forces of a loosened mass during rotation of the shredder are possible. This, in turn, leads to increased mechanical stress on the elements of the shredder and energy costs.

 The present invention is aimed at improving the efficiency of collapse of highly bonded low-flowing materials and the reliability of the mechanism for collapse.

 The solution to this problem is achieved by the fact that the bunker for bulk materials contains a housing and a shredder placed in it, including a horizontal shaft with disks. The disks are mounted on a cylindrical support sleeve covering the drive shaft of the shredder, and the disks are mounted on a cylindrical sleeve at an angle to the axis of the shaft equal to or greater than the angle of repose of the material. In this case, the adjacent discs are inclined towards one another. The shaft breaker is equipped with a vibration exciter, which is made in the form of a helical central gear rigidly connected to the cylindrical supporting sleeve of the shaft breaker, the free-wheeling mechanism and unbalanced satellites. The axis of the satellites are connected to the exciter housing through the freewheel mechanism. Between the exciter housing and the helical central gear, elastic elements are installed.

 Comparative analysis with the prototype allows us to conclude that the inventive bunker for bulk materials is characterized in that the shredder is equipped with a vibration exciter made in the form of a helical central gear connected to a sleeve enclosing the drive shaft, on which disks, the free-wheeling mechanism and unbalanced satellites are fixed. In this case, the axis of the satellites are connected to the vibration exciter housing through the freewheel mechanism, and elastic elements are located between the vibration exciter housing and the helical central gear.

 With such a constructive solution of the bunker for bulk materials, the actuator of the shredder performs a complex motion: the rotational motion is superimposed on the rotational and reciprocal axial movements. The geometrical characteristics of the trajectory of motion, the dynamics and the direction of the force action from the side of the working elements of the shredder disks on the sealed and packed material arch contribute to a more effective collapse during overloading of strongly bonded low-bulk materials.

 The drawing shows the proposed bunker device for bulk materials, General view.

 The hopper contains a truncated cone-shaped housing 1, a horizontal drive shaft 2 passed through the walls of the hopper located in the zone of possible material arch formation, and a shaft breaker made in the form of a group of disks 3 rigidly mounted on a cylindrical support sleeve 4 covering the drive shaft 2. When this discs 3 are fixed at an angle to the axis of the shaft equal to or greater than the angle of repose of the material. The cylindrical sleeve 4 of the shaft breaker covers the drive shaft 2 and is mounted on the shaft by means of a sliding key-groove joint that can be moved along it. The shaft breaker is equipped with a vibration exciter, which is made in the form of a helical central gear 5, rigidly connected to the cylindrical sleeve 4 of the shaft breaker, a free-wheeling mechanism 6 and satellites 8 mounted on the carrier 7, engaged with a helical central gear 5. In this case, the satellites are equipped with unbalanced unbalanced unbalances 9 , and the axis 10 of the satellites are connected with the housing 11 of the exciter through the freewheel 6. Between the housing of the exciter and the helical central gear 5, elastic All elements 12 and 13.

 Holes 14 are formed in the disks 3 of the shaft breaker. The cross section of each hole provides a material throughput.

 The disks 3 are mounted on the cylindrical sleeve of the demolisher in such a way that each subsequent one is inclined towards the previous one, forming cavities close to the shape of the funnel.

 Fixing the disks on the cylindrical supporting sleeve of the shaft breaker at an angle to its axis equal to or greater than the angle of repose of the bulk material reduces the coefficient of friction between the material and the surface of the disks.

 Depending on the physicomechanical properties of a particular bulk material, the shape and height of the hopper, several shredders can be mounted in the latter.

 The device operates as follows.

 Material loaded through the upper part of the hopper using a conveyor (not shown) or in any other way, in the initial period, the demolisher passes unhindered and is poured through the unloading window. As the layer of material loaded into the hopper increases, its compaction and arch formation occurs.

 Upon termination of the flow of material from the hopper, which indicates the formation of the vault, include a drive that informs the shaft breaker with inclined disks 3 rotational movement, each of which end and side surfaces affects the mass of compacted material. Simultaneously with the rotation of the shaft 2, the shaft breaker is driven into rotation and the helical central gear 5, rigidly connected to the cylindrical support sleeve 2 of the shaft breaker. The helical central gear 5, in turn, drives the unbalanced satellites 8. The centrifugal force resulting from the imbalance acts on the axis 10. The carrier 7 and axis 10 move only in the direction opposite to the rotation of the shaft 2 of the shaft breaker, which is ensured by the free-wheeling mechanism 6, such Thus, each revolution of the satellites 8 gives an impulse to the carrier 7 (duration 1/2 revolution) in the direction opposite to the rotation of the shaft and, accordingly, to the disks 3 of the shaft breaker.

 The unbalanced satellites 8 make a complex movement relative around the axes 10 and figurative around the axis of the shaft 2. As a result of the figurative movement, the satellites 8 are subjected to centrifugal inertia forces, which impose reciprocal rotational impulses on the helical central gear 5, which are sinusoidal in nature, and the full cycle corresponds to one rotation of unbalanced satellites 8. Under the influence of these reciprocating rotational pulses in helical gearing, forces arise that displace the helical central gear 5 in axial direction. Under the influence of a positive impulse, the helical central gear shifts to the right, and under the influence of a negative impulse to the left (or vice versa, depending on the direction of cutting the teeth). The elastic elements 12 and 13 ensure smooth axial movements of the cylindrical sleeve 4 with the disks 3 and limit them.

 Thus, the shaft breaker with the disks 3 makes a complex movement on the rotational movement; the reciprocating and reciprocating axial movements are superimposed. The trajectory of the disks 3 is a complex curve, which has an uneven sinusoidal character. The geometric characteristics of the trajectory of motion, the dynamics and direction of the force action of the disks of the vault demolisher on the bulk of the bulk cargo contribute to a more effective destruction of the stable bonds of the material and the collapse of the arches.

 Since the adjacent disks of the cave-breaker are inclined towards each other and form cavities close to the shape of the funnel, they rotate simultaneously cutting the arch, loosening the material, grabbing it in portions and scattering inside the hopper, increasing the rate of precipitation through the hopper discharge window.

 With a cyclically repeating process of movement of the demolisher, the flow of material in the funnel-shaped cavities of the inclined disks makes more complex spatial movements, and its adjacent layers have stepwise phase shifts; upon contact of the material with the surface of the disks and under the influence of force impulses on their side, there is a break in the continuity of the flow, destruction of the cohesion of its constituent particles and layers and at the same time equalization of the flow due to the additional redistribution of the bulk material vertically inside each funnel-shaped cavity and horizontally between adjacent cavities through openings 14 in disks 3 arch breaker. The pouring of material from the cavity into the cavity between the disks of the shredder also contributes to the intensive loosening of the material and its expulsion from the cavity.

 The intensification of the process of the impact of the shredder on the overloaded material is accompanied by the elimination of stagnant zones, the sticking of material on the disks and the passage section overgrowing between adjacent disks at the level of their smallest angular opening.

 The design feature of the proposed device in comparison with the known devices provides due to the angular pulsed vibrations and axial movements of the shredder an efficient process of collapse of materials prone to the formation of stable arches and freezing, and uniform outflow of material from the hopper into technological installations and transport and technological equipment, which improves operational hopper capabilities, increase unloading performance with relatively low energy awn drive.

Claims (1)

 Bulk hopper for bulk materials, comprising a housing and a casing demounter housed therein, including a horizontal shaft with obliquely mounted discs, adjacent to which are inclined towards one another, characterized in that the casing demounter is equipped with a vibration exciter consisting of a helical central gear connected to a cylindrical supporting shaft that drives the drive shaft a sleeve with disks fixed to it, a freewheel and satellites with unbalances fixed to them, while the axis of the satellites are connected to the housing ibrovozbuditelya through the freewheel mechanism and the vibration exciter is provided with elastic elements arranged between the housing and exciter central helical gear.