UA28667U - Device for removal of deposits from wall - Google Patents

Abstract

A device for removal of deposits from a wall contains a generator of pulse currents connected to an actuating mechanism installed from the opposite side of possible deposit being part of a pancake coil mounted on the rigid basis fixed relative to the wall, and a flat armature from the high-conductivity material rigidly secured to the wall. The flat armature is mounted perpendicularly to the normal to the wall with a clearance relative to wall and it is rigidly secured to the wall by means of at least one rod. The pancake coil inductor is located between the wall and the flat armature.

Description

Description of the invention

The useful model refers to devices for preventing the formation of vaults and cleaning the walls of bunkers and 2 other surfaces from deposits of various materials and can be used in various industries where there is storage, transportation and overloading of materials prone to sticking and freezing.

A known device for preventing the formation of vaults and cleaning the walls of bunkers, as well as other surfaces from adhering material, containing a generator of impulse currents and an executive mechanism consisting of a flat 70 inductor, mounted on a rigid base, rigidly fixed to the wall of the bunker, and a flat anchor made of highly conductive material, located with a gap relative to the flat inductor and rigidly fixed to the wall of the bunker from the outside (on the opposite side from the formed vault or stuck material (patent of the Russian Federation Mo2153403, MKV VO8B 7/02, 19981).

The disadvantage of the device considered as the closest analogue is the insufficient efficiency of vault collapse and 12 cleaning of the surfaces of the walls of bunkers due to a large mass of adhered material and high adhesion strength, characteristic of wetted materials, such as iron ore concentrate, bauxite, charge, ore, etc., in connection due to the fact that when acting on a section of the hopper wall with a force pulse directed towards the formed vault or the adhered material, it is impossible to achieve large values of acceleration of the particles of the adhered material relative to the surface being cleaned, sufficient to overcome the adhesion forces, since the adhered material under the action of a force pulse, it moves together with the wall and, in addition, dampens the oscillations of the wall.

The technical task of the useful model is to improve the device for cleaning the wall (for example, a hopper) from deposits (for example, loose material that has stuck or accumulated), which contains a generator of pulse currents and an executive mechanism installed on the opposite side of the wall to the deposit in the form of a flat inductor, mounted on a rigid base, rigidly fixed relative to the wall, and a flat anchor of 22 highly conductive material, rigidly fixed to the wall, by installing a flat anchor -o perpendicular to the normal to the wall with a gap to the wall, rigidly fixing the flat anchor to the wall or to a spring plate using at least one rod and the location of the flat inductor between the surface to be cleaned and the flat armature.

When acting on a section of the wall, for example, on a section of the wall of a bunker, with a force unit impulse - 30 directed in the direction opposite to the formed vault, or the stuck material, the movement of the section of the wall "o" from the initial position to the side free from the stuck material begins, i.e. in air, which leads to the emergence of a force of detachment of the wall section from the adhered material and an elastic force that tends to return the wall section to its initial position. At the first stage of this process, when the elastic force exerts a minimal opposition to the force about the momentum, its energy is aimed at overcoming the force of adhesion of the material to the wall. But since the movement 325 occurs in the direction free from the adhered material, the area of the wall can be given the acceleration necessary to overcome the adhesion force. The material detached from the wall remains in place in the form of a layer that rests on the layers below, or under the influence of gravity moves downwards, for example, to the bottom of the hopper, and the wall section continues to move. After the section of the wall reaches the maximum deviation, its movement in the reverse direction begins, caused by the action of elastic forces. At this stage of the process, the potential C 70 energy of the buckled wall turns into the kinetic energy of the section of the wall moving in the opposite direction, which takes the maximum value after reaching the maximum speed, i.e. at the moment of transition from the section of the wall to the initial position. At the moment of time, close to the moment of passage of the primary position, the section of the wall moving at the maximum speed collides with the material that was exfoliated at the first stage of the process, and additionally contributes to the destruction of the formed vault. If in the process of 75 movement of a section of the wall with a layer of adhered material in the reverse direction after it reaches its maximum speed, i.e. at the moment of passing the initial position or a little later, but no later than when it reaches the extreme position of deflection in the reverse direction, the further movement of the section of the wall is instantly prevented in the opposite direction, for example, inside the hopper, the stuck material moving at a high speed acquires a significant acceleration relative to the stopped section of the wall, which leads to the emergence of a force

Gee! 20 of the inertia of the adhered material, which is equal to the product of its mass and the acceleration, which is sufficient to overcome the adhesion force of the material to the wall even in the case when, at the first stage of movement of the wall section under the action of the force tm pulse in the direction free from the adhered material, the material does not peel off ( which can occur with high adhesion and viscosity of the adhered material or with a small thickness of the layer of adhered material).

Thus, high values of the acceleration of the wall section itself, for example, the wall of the hopper, are achieved, and also give particles of adhered material a high acceleration relative to the surface being cleaned, as a result of which a technical result is achieved, which consists in creating forces whose values are sufficient to destroy adhesion between the surface to be cleaned and the adhering material, which helps to increase the efficiency of cleaning surfaces with a large mass and high adhesion strength of the adhering material, in particular, the high efficiency of vault collapse and prevention of vault formation in bunkers. because the device for cleaning the wall (for example, the wall of the hopper) from deposits (for example, deposits of stuck or settled loose material) has in its composition a pulse current generator connected to the side of the wall installed on the opposite side of the possible deposit (that is, on the side of the wall opposite to , on which a deposit may be formed; for example, from the outside of the hopper wall in the case of cleaning the hopper wall from the deposit of stuck or settled bulk material) by an executive mechanism consisting of a flat inductor mounted on a rigid base rigidly fixed to the wall, and a flat armature made of highly conductive of material rigidly fixed to the wall, while the flat armature is installed perpendicular to the normal to the wall (that is, parallel to the flat wall or parallel to the plane tangent to the cylindrical wall) with a gap relative to the wall and rigidly fixed to the wall with at least one rod, and the flat inductor is located between the wall and the flat anchor . The flat anchor can be installed with a gap relative to the flat inductor, while on the rigid base on which the flat inductor is installed, diametrically spaced relative to the axis of the coil of the flat inductor and stops parallel to this axis can be rigidly fixed, the unfastened ends of which have the possibility of contact with the one facing the wall surface of the flat armature and form a gap relative to it smaller than the gap between the flat armature and the flat inductor. 70 Fig. 1 shows a variant of the device for cleaning the wall from deposits; Fig. 2 shows the scheme of selecting the moment of instantaneous stop of the reverse movement of the wall or elastic plate caused by the action of elastic forces.

The device for cleaning the wall of the hopper 1 from deposits of sticky material 2 contains a pulse current generator З, which is connected to an executive mechanism located on the outside of the wall of the hopper 1 (on the opposite side from 7/5 of the deposits 2 -- the formed vault or sticky material) in composition of a flat inductor 4, installed on an elongated rigid base 5, rigidly fixed at the ends relative to the wall of the hopper 1, and a flat armature b made of highly conductive material, installed with a gap a. relative to the wall of the hopper 1 in such a way that the flat inductor 4 is located between the wall of the hopper 1 and the flat anchor 6. The flat anchor 6 is located with a gap ao relative to the flat inductor 4, and on the rigid base 5, on which the flat inductor 4 is installed, stops 7 are rigidly fixed , spread diametrically relative to the axis of the coil of the flat inductor 4 and parallel to its axis, while one end of each of the stops 7 is rigidly fixed to the rigid base 5, and between the other, unsecured end of each of the stops 7 and the surface of the flat anchor facing the wall of the hopper 1 b there is a gap az, the size of which is smaller than the gap ao between the flat inductor 4 and the flat anchor 6. With the help of one or more rods 8, the flat anchor b is rigidly fixed to the wall of the hopper 1.

The device for cleaning the wall from deposits is used as follows.

With the help of the pulse current generator Z, a discharge current o of large amplitude is passed through the flat inductor 4, which excites the electromagnetic field in the gap ag between the flat inductor 4 and the flat armature 6.

This electromagnetic field, in turn, excites an eddy current in the flat armature b. The interaction of the pulsed magnetic fields created by the discharge and excited currents leads to the occurrence of a pulsed force that repels the flat armature 6 from the flat inductor 4 mounted on the rigid base 5. Since the flat armature is rigidly fixed with the help of a rod 8 to the wall of the bunker 1 , then together with the flat anchor 6 from the depicted x, in Fig. 3 of the primary position | the corresponding part of the wall of the hopper 1 begins to move in the direction opposite to the formed vault or stuck material 2, that is, to the outside in the form of a layer that rests on the lower layers or moves to the lower part of the bunker under the influence of gravity, and the wall of the bunker continues to move. Reach the maximum deviation in the position shown in Fig. 3

Thus, the wall of the hopper 1 under the action of the elastic force begins to move to the initial position I shown in Fig. 3. At this stage of the process, the potential energy of the wall of the hopper 1, which has buckled, turns into the kinetic energy of the wall of the hopper 1 moving in the opposite direction, which takes the maximum value after reaching "the maximum speed, i.e. at the time of passing through the wall of the bunker 1 of the initial position shown in Fig. 2). nta) c At the moment of time, close to the moment of passage through the wall of the bunker 1 shown in Fig. 2 of the initial position. the wall of the hopper 1, moving at the maximum speed, collides with the material 2, which has peeled off at и? the first stage of the process, and additionally contributes to the destruction of the formed vault. If at the initial stage of the movement of the wall of the hopper 1 under the influence of the impulse force, it does not detach from the adhered material 2 (which may have

Place with a small layer of adhered material 2, when it is separated layer by layer as a result of overcoming the cohesive forces in the layer of adhered material, etc.), then further movement of the wall of the hopper 1 occurs with a certain layer of adhered material 2. At the moment of passage through the wall of the hopper 1 of the depicted in Fig. 3 of the primary position I, when the speed of its movement reaches the maximum value, or at the moment when the wall of the bunker 1 b is in position III after passing through the primary position I, but before reaching the extreme position

M of the deflection in the opposite direction (inside the bunker, in the direction of the stuck material 2), the flat anchor 6 hits

Me, about the stops 7, are rigidly fixed relative to the rigid base 5. As a result, the wall of the hopper 1, which is rigidly

And connected by means of a bar 8 to a flat anchor 6, it stops instantly. At the same time, the adhered material 2, moving at a high speed, acquires a significant acceleration relative to the stopped wall of the hopper 1, which leads to the emergence of the inertial force of the adhered material 2, which is equal to the product of its mass and the acceleration, sufficient to overcome the adhesion force of the material 2 to the wall of the hopper 1 .

Stops 7 in the initial position of the flat anchor can be adjacent to it without a gap. In this case, at the moment of impact of the flat anchor 6 against the stops 7, the speed of movement of the wall of the bunker 1 is maximum, therefore, it is the maximum acceleration obtained by the adhering material 2. However, in the case of separation of the wall of the hopper 1 from the adhering material 2 already at the initial stage, this variant of the location of the stops 7 is not optimal, because the stops 7 prevent additional destruction of the formed vault. Therefore, it is advisable to place the stops 7 in relation to the flat anchor 6 with a gap az, the size of which should be less than the gap a"; between the flat inductor 4 and the flat armature 6. The choice of this gap ratio excludes the possibility of the flat armature 6 colliding with the flat inductor 4 and the related destruction of the latter.

The use of the proposed device for cleaning the wall from deposits allows you to significantly increase the efficiency of magnetic pulse installations used to prevent the formation of vaults and to clean the walls of hoppers and other containers used in the sintering plant from adhering material.

blast furnace, foundry production, mining and other industries.

Claims (2)

The formula of the invention 1. A device for cleaning the wall from deposits, containing a generator of pulsed currents, connected to an executive mechanism installed on the opposite side of the wall from possible deposits, consisting of a flat inductor, mounted on a rigid base rigidly fixed relative to the wall, and a flat anchor made of 70 highly conductive material, rigidly fixed to the wall, which is distinguished by the fact that the flat armature is installed perpendicular to the normal to the wall with a gap relative to the wall and rigidly fixed to the wall with at least 6 one rod, and the flat inductor is located between the wall and the flat armature. 2. The device according to claim 1, which is characterized by the fact that the flat armature is installed with a gap relative to the flat inductor. C. The device according to claim 2, which differs in that on a rigid base, on which a flat inductor is installed, rigidly fixed coils of the flat inductor diametrically spaced relative to the axis of the flat inductor and stops parallel to this axis, the loose ends of which have the opportunity to contact the surface of the flat armature facing the wall and form a gap with it smaller than the gap between the flat armature and the flat inductor. that 2 in (Se) (Se) (ee) p - and? ime) (ee) (o) (o) that 60 b5