SE455050B - VIBRATOR INTENDED TO BE POWERED BY AN UNDER PRINTED MEDIUM - Google Patents

Description

455 050 cause a pivoting movement, which results in the movement of the bulk material.

The disadvantages of these known vibrators are that they have complicated construction, great weight and low operational safety during operation in dusty, abrasive and aggressive media, for example under shaft conditions. These known vibrators also lack means for automatically adapting the excitation forces to the actual oscillations of the shaking platforms, which leads to the vibrator being overloaded, whereby the electric motor often operates under starting conditions or is phase-reversed. Such operating conditions in combination with considerable vibration stresses lead to the electric motor being quickly made inoperable. To limit the effect of all factors, one must increase the power of the motor to effect the rotational movement, which, however, causes the bearings on the shaft of the imbalance weights to be overloaded and quickly goes out of operation. real oscillating forces.

The pneumatic and hydraulic motors for effecting the rotational movement must necessarily include an expensive kinematic precision pair, for example rotor-stator, piston-cylinder, gear. In order to prevent the said pair from wearing out quickly, one must carefully clean an energy transfer medium, for example compressed air, continuously feed lubricants to the friction surfaces and continuously inspect and maintain them. These motors have low functional safety when working in damp, aggressive and dusty media, for example in shafts.

In order to be able to transport bulk material more efficiently, the shaking platform must be excited continuously. Pneumatic or hydraulic percussion vibrating piston vibrators are known, which vibrators comprise a housing with a cylinder in which a piston-shaped percussion member is movable, and a system for feeding and diverting an energy transfer medium. The piston itself often functions as a distribution means, for which purpose the piston and the cylinder are provided with special inlet channels and closing edges. These known vibrators also require careful purification of the energy transfer medium and continuous lubrication of the piston group and work poorly in aqueous and abrasive media. The speed of movement of the piston-shaped 455 050 percussion member generally exceeds - before the stroke is carried out - 5-6 m / s, which adversely affects the strength of the vibrator and the shaft conveyor device, as this leads to the occurrence and rapid spread of microcracks in the structural members and then to crime on the same. To reduce the stroke speed, the diameter of the piston and cylinder must be increased, which is not economical. In addition, the means for distributing the energy transfer medium become more difficult to construct by reducing the stroke of the piston.

Membrane-type vibrators are further known, which vibrators comprise a force chamber formed by a housing and a diaphragm. The membrane is intended to influence the shaking platform of a shaking transport device via an intermediate part. The energy transfer medium is often distributed by means of a slide valve device. The slide valve is movable by means of the diaphragm.

With these known vibrators, some of the above disadvantages are eliminated. With these known vibrators, however, it is more difficult to construct an outlet distribution device due to the fact that the diaphragm has a short path of movement. The slide valve distribution also requires cleaning of the energy transfer medium, continuous lubricant supply and protection against abrasive particles from the surrounding medium ending up in the vibrator.

A diaphragm vibrator for driving a shaft transport device is also known, which device is a working platform supported by means which enable the working platform to move in the longitudinal direction. The work platform is provided with a spring device for returning this platform to the initial position. This known vibrator comprises a housing arranged stationary in relation to the work platform. A study in the house has an elastic membrane-shaped wall, which is attached along the periphery. A valve device for compressed air supply to the workroom is arranged in the housing. Attached to the center part of the diaphragm is a rigid ring, the opening of which is connected to the workroom. The ring is provided with a sealing belt, to which a valve adjoins. The ring is movable together with the center part of the diaphragm and comes into abutment against a member arranged on the housing for limiting the stroke of the ring. The valve is supported by a rod, which is attached to the end surface of the work platform.

During the work process, the compressed gas flows into the work room via the inlet device 455 050. The compressed air acts on the diaphragm, which is bent out by its elasticity, the diaphragm moving as far as possible in its center part together with the rigid ring attached to it, which by means of its sealing belt is pressed against the valve and via the valve and its rod transmits the central part of the diaphragm the power of the work platform. This force acts so that the working platform moves in the longitudinal direction and thereby compresses the return spring, at the same time as the rigid ring of the diaphragm comes into abutment against the stop and limits the continued movement of the diaphragm. The work platform continues to move through inertia and carries the valve. the valve moves away from the ring of the diaphragm, which results in the compressed gas being diverted from the working space via a gap formed between the ring and the valve and the center hole of the ring to the atmosphere. At this time, the supply of pressure to the workroom is interrupted by means of the inlet device arranged in the housing. The membrane then returns together with the ring to the initial position under the influence of its elastic forces or by other special means. Under the influence of the return spring, the working platform performs a return stroke until the valve is pressed against the diaphragm ring. The workroom is hermetically sealed and the compressed gas begins to be fed into it, after which the work process is repeated.

This known vibrator has not found a wide range of uses due to its low power. The force to be provided in the working space of this known vibrator cannot be transmitted over the diaphragm to its center ring and the working platform due to the fact that the working surface of the diaphragm is rapidly reduced while the diaphragm is bent out. This is caused by the membrane in the area from the peripheral part to the center part beginning to stretch up to its deformation limit and then ceasing to participate in the useful movement work of the work platform.

These known vibrators are also complicated and include complicated inlet and outlet devices, which wear out quickly and do not work safely in dusted abrasive media.

Vibrators of so-called cuff types are also known, which vibrators are fluid-driven and intended for operation of, for example, shaft transport devices. The working platform of these known vibrators is arranged to perform oscillations in a direction which is perpendicular or inclined 455 050 towards the surface of the working platform, or in the form of a traveling longitudinal wave, when the working platform is of rigid design. This known vibrator comprises a stationary foundation, a work platform and a cuff arranged therebetween, which are arranged to form a work space. The cuff can be attached to the foundation or work platform or simultaneously to the foundation and platform.

The sleeve is necessarily provided with at least one outlet hole, the elastic edges of which are arranged to be periodically hermetically pressed against the surface of the foundation or work platform under the action of the fluid pressure in the working space. The working stroke for the deflection of the elastic sealing edge of at least one outlet hole in the sleeve and over at least one portion is less than the entire stroke of the work platform with a value required for an outlet channel formed between the sleeve and the work platform or foundation to be able to get the desired cross-sectional area. To change the deflection distance of the sealing edge of the sleeve, this must be provided with a means for limiting the stroke.

Although these known vibrators have many positive properties, they cannot produce an active shock excitation force which can effectively transfer the material to be treated to a dynamic state. Nor do these known vibrators exhibit a sufficiently high shock excitation frequency due to the fact that the return stroke of the work platform is relatively passive. For these reasons, these known vibrators have a low impact power. These properties are in many cases also required for shaft transport devices in order to increase their transport capacity, especially when transporting a viscous adhesive material.

The main object of the invention is to provide a vibrator which can excitedly excite the work platform with a large effect by a suitable change in the construction of the vibrator.

This is achieved according to the invention by means of a vibrator, which is driven by a pressurized medium in order to cause the work platform with the material to be treated on it to perform vibrations, which vibrator comprises a foundation with one on it at the working platform side arranged elastic sleeve, which is arranged to form a working space and built in the form of a closed ring with at least one outlet hole with an elastic edge, which is arranged to perform oscillating movements under the action of the fluid and is intended to allocate the work platform vibrations, wherein according to the invention on the side facing the work platform a strut is arranged, which is intended to co-operate with the work platform, when the cuff performs oscillating movements under the action of the pressurized medium, and to assign striking vibrations to the work platform.

Such a constructive design of the vibrator makes it possible to actively excite the work platform and consequently the material lying on it, which is to be treated, and to provide a vibrator with a large impact effect. The energy and frequency of the shock excitation force of the work platform can be partly regulated by changing the amount of pressurized fluid to be supplied to the vibrator, for example by means of a valve. The vibrator has a constructively simple design and is free of precision friction parts. The vibrator can also have small outer dimensions and low weight per unit of the vibrator's impact effect, works safely in aggressive, damp, dusty, abrasive media and t.o.m. under water-rich ambient conditions and does not require lubrication and purification of the fluid from any foreign inclusions.

The vibrator according to the invention is easy to maintain, does not require any systematic technical maintenance and lubrication. Nor does it need to be protected against the influence of the surrounding medium by means of special protective means.

All the advantages of the proposed vibrator contribute to it being able to have a wide range of uses in various machines and mechanisms for varying technical purposes.

The weight of the impactor suitably exceeds the elastic deformation force of the cuff.

This makes it possible, by means of simple means, to increase the impact force of the vibrator and to reduce the speed at which the impact stress is applied to the work platform, which results in an increase in the life of the vibrator and an increase in the life of the object which is caused to perform oscillating movements by the vibrator. , and in reducing the likelihood of fatigue micro-cracks forming and spreading in the parts of machines and mechanisms that are to be subjected to a striking vibration stress. It is advantageous in several cases that the impactor is connected to the foundation by means of at least one elastic element, which acts in such a way that the impactor quickly returns to the initial position.

Such a constructive solution contributes to considerably increasing the impact load frequency, and to preventing the impact body from being displaced laterally on the foundation by means of simple devices. - It is very appropriate that the foundation is attached to the work platform.

This makes it possible to transmit the vibrating recoil force of the vibrator in the form of an impact-free or striking force pulse to the work platform and over it to the material to be treated, in order to amplify the vibrations of the material, and to increase the load frequency of the work platform and the vibrator. efficiency. The connection of the foundation to the work platform can be made rigid or elastic or resilient. In the latter cases, the peak stresses at the connecting elements are reduced, which results in an increase in the service life of these elements. The energy to be stored in the elastic or resilient connections is also efficiently transferred to the work platform and over it to the material to be treated, whereby the vibrations of the material are amplified.

In certain cases it is suitable that the impactor of the vibrator is connected to the working platform or the foundation by means of connecting links, which are intended to limit the movement of the impactor in a plane which is parallel to the working platform.

This makes it possible to freely orient the vibrator in the space without deteriorating its starting and functional properties. If said connecting links consist of an elastic plate or flexible wires, the vibrator can be placed at any angle to the horizontal plane.

This also contributes to an easier start-up and a smoother vibrator function in that the impactor is not skewed in the contact plane of the impactor with the elastic edge of the outlet hole of the cuff.

It is advisable for the cuff to be attached to the impactor.

This makes it possible to replace the sleeve together with the percussion member without removing the foundation or detaching it from the work platform. 4ss 050 8 In some cases it is advantageous that the elastic edge of the outlet hole of the cuff is provided with an element for forced return of said edge to the initial position.

This makes it possible to increase the effect of the vibrator especially when the vibrator is driven by a liquid liquid medium as a result of the cross-sectional area and opening time of the outlet channel being made larger, which improves the discharge conditions for the effluent fluid from the working space to the surrounding medium.

It is furthermore suitable that the working space of the vibrator is provided with a valve device arranged at its inlet, through which the fluid is supplied to the working space and the supply of fluid to the working space is interrupted, respectively, when the drain fluid is diverted from it to the surrounding medium.

This contributes to a decrease in fluid consumption and consequently to an increase in the efficiency of the vibrator and to an increase in the impact effect of the vibrator through a reduced back pressure in the working space at the return of the impactor, which leads to an increase in the impact length of the impactor.

The present invention has provided a series of vibrators with different stroke power and stroke frequency, which make it possible to actively excite the material to be treated by vibration. All vibrators work safely under very strict ambient conditions.

The invention is described in more detail below with reference to the accompanying drawings, in which Fig. 1 schematically shows an impact vibrator according to the invention, in which the impact body is connected to a stationary foundation by means of elastic elements, Fig. 2 shows the vibrator according to Fig. 1 at a time when the impactor strikes the work platform, Fig. 3 schematically shows an impact vibrator according to the app invention, to which the foundation is attached to the work platform, while the cuff has a C-shaped cross section, Fig. 4 shows the vibrator shown in Fig. 3. at the time when the impactor strikes the work platform, Fig. 5 schematically shows an impact vibrator according to the invention, in which the foundation is connected to the work platform by means of a spring suspension member, while the cuff is provided with a remote controllable means for limiting the mane 455 050 Fig. 6 shows the stroke length, while the impact body is connected to the foundation by means of an articulated element, Fig. 6 shows an Fig. 7 schematically shows a special vibrator according to the invention, in which the impactor is connected to the work platform by means of a double link piece, while the cuff is provided with an element for forced return of the elastic sealing edge of the sleeve to the initial position, the working space being provided with a valve device, Fig. 8 schematically shows an impact vibrator according to the invention, in which the sleeve is arranged between the working platform and the impact body, while the return spring for returning the impact body to the initial position is arranged between the impactor and the foundation and Fig. 9 shows an embodiment of the vibrator, in which the impactor is connected to the working platform by means of springs.

In the drawings, arrows indicate the direction of supply of the fluid to the vibrator and the direction of outlet thereof from it.

In describing embodiments of the invention with reference to the accompanying drawing, a particular terminology is used.

It should be noted, however, that each such term encompasses all the equivalent elements which function in a similar manner and are used to achieve the intended purpose. The term "cuff" refers, for example, to all elastic or resilient elements of varying shape, which in at least one place hermetically seal the working space of the vibrator under the action of the fluid pressure in this space.

The vibrator shown in Figs. 1, 2 is used in combination with a shaker transport device, for example a shaker feeder. which is arranged in an outlet mine for self-propelled discharge of the rock from a so-called quarrying blocks, transport and loading of this into a mobile transport device, for example a conveyor, a trolley or the like. The vibrator comprises a foundation 1, which in this embodiment of the invention is stationary attached to the ground surface in an outlet mine: and a work platform 2 arranged above the foundation 1, which in this embodiment has a large surface and acts as the shaker platform of the feeder. One end of the shaking platform is arranged below the outlet funnel of the quarry section, while its other end is inclined and faces the container of an accessible transport device. Arranged on the foundation 1 is a cuff 3, which is intended to hermetically close a working space 4. On the cuff 3, between the foundation 1 and the working platform 2, a striking body 5 arranged in the form of, for example, a plate is arranged. The impact body 5 is arranged to effect a reciprocating movement between the foundation 1 and the work platform-2 under the action of a fluid pressure in the work space 1 and to cooperate with the work platform 2 and thereby assign it impact vibrations. The cuff 3 is provided with at least one outlet hole 6, the elastic sealing edge 7 of which is intended to hermetically close the working space 4 when the impact body 5 moves forward, i.e. when it moves upwards according to Fig. 1, and to interrupt the hermetic closure of the space 4 before the impact body 5 blows to the work platform 2 (fig. 2). The cuff 3 may be of any suitable shape which helps to hermetically close the working space 4 as the impactor 5 moves forward, and to interrupt the hermetic closure of the chamber 4 at the end of the movement of the impactor 5, and to hermetically close the working space 4 at the final distance. of the body's return movement. The cuff 3 can be made of any resilient or elastic material, for example polymer, rubber or even metal or a combination thereof. The cuff 3 can also be made of rubberized fabric, reinforced with polymeric material, steel mesh or wire.

It can t.o.m. made entirely of steel, while its sealing edges can be reinforced with an elastic material. Depending on the design, the cuff 3 can be arranged in the vibrator without it being rigidly attached.

Alternatively, it can be attached to the foundation 1 or to the impact body 5, as shown in Figs. 1, 2, or to the foundation 1 and the body 5.

If the sleeve is attached to a foundation (not shown), at least one outlet hole 6 therein faces the impact body 5, while the elastic sealing edge 7 of this hole is intended to be hermetically sealed against the sealing surface of the impact body 5 under the action of the fluid pressure in the working space 4. If the cuff 3 is attached to the striker 5, as shown in Figs. 1, 2, at least one outlet hole 6 therein faces the foundation 1, while its elastic sealing edge 7 is intended to be pressed against the sealing surface 8 of the foundation 1 under the action of the fluid pressure in the working space 4. If the cuff 3 is provided with an upper and a lower elastic sealing edge, which are intended to hermetically close the working space 4 from above and the cuff 3 from below under the action of the fluid pressure, the cuff 3 cannot be attached to the foundation 1 or the impact body 5.

The movable elastic sealing edge 7 of at least one outlet hole 6 in the cuff 3 and over at least one portion must move the distance of movement for deflection of said edge 7 which is less than the stroke of the impactor 5 in one or the other the direction. This is required in order for an outlet channel 9_ (Fig. 2) to be formed between the edge 7 and, for example, the sealing surface of the foundation 1, which channel is intended to connect the working space 4 to the surrounding medium in order to divert the drain fluid from the space 4. deflection distance can be limited in various ways by using a means for limiting the travel stroke of the edge 7, which means can for instance consist of a flexible connecting link, which is intended to interrupt the movement of the edge 7 over a predetermined deflection. or, for example, by increasing the stiffness of the movable part of the cuff, for example by increasing its thickness or by choosing a stiffer material. Figs. 1, 2 show an embodiment in which the stroke of the elastic sealing edge 7 of the outlet hole 6 of the sleeve 3 is limited by suitable choice of the material, the width of the edge 7 and the annular cross-section of the outlet hole 6, which in combination with each other at the calculated fluid pressure contributes to the edge 7 being bent out to the greatest possible, predetermined degree from the initial position shown in Fig. 1 (along the entire perimeter of the working space 4, in this embodiment of the invention).

Seen in a plane parallel to the foundation 1, the work space 4 can have any constructively suitable shape, for example square, parallel logram-shaped, triangular, circular, etc. The pressurized fluid flows into the work space 4 via a choke channel 10, a fluid source not shown in the drawing is intended to be connected to the vibrator via a pipeline 11, which is for example attached to the foundation 1. Instead of the throttle channel 10, a valve-equipped or other inlet device can be used. In order for the impactor 5 to be able to return to the initial position more efficiently and more quickly, the weight of the body 5 must exceed the total elastic deformation force of the cuff 3 in its compressed boundary position, when the volume of the working space 4 is as low as possible. If the vibrator must be driven at a higher frequency, the striker 5 should be connected to the foundation 1 by means of at least one elastic element, for example springs 12 (Figs. 1, 2) so that the latter cause the body 5 to quickly return to the initial position. If the angle of inclination between the vibrator and the horizontal is small, the springs 12 can certainly prevent the impact body S from being displaced laterally in a plane parallel to the foundation 1. In order to dampen the impact stresses, an elastic intermediate position (a strip) 13 can be arranged between the working platform 2 and the body 5, which is attached to the impact body 5 and designed as shown in Figs. 1,2. On the work platform 2, which in this embodiment functions as a shaker platform of a feeder, a rock mass 14 is moved.

Fig. 3 shows an embodiment of the vibrator, to which a foundation 15 is attached to a work platform 16 by means of rigid, elastic or resilient connecting links 17, which make it possible to transmit the counteracting recoil force into the vibrator to be accommodated by the foundation 15. , to the shaking platform 16 in order to amplify the vibrations thereof together with the material (not shown) lying on the platform 16 to be treated. Fig. 3 shows the embodiment in which a cuff 18 has a C-shaped cross-section along a closed contour, is provided with several outlet holes 19 and is attached to the foundation 15 or to a striking body 20, which prevents the body 20 from displacing laterally relative to the foundation 15. This displacement is further prevented by means of springs 21, which are arranged between the platform 16 and the body 20 and enable the body 20 to quickly return to the initial position.

In order to reduce the ineffective volume of a working space 22, the space 22 can be filled with a filler 23 connected to the foundation 15, which at the same time can function as an anvil to continuously brake the impact body 20 at the end of its return. The filler 23 can be made of a hard material or, in order to dampen the blows to be absorbed, an elastic material, e.g. rubber. Fig. 4 shows the same vibrator at a time when the impactor 20 strikes the work platform 16. Then, between the elastic sealing edge of the outlet holes 19 and the associated abutment surface of the impactor 20, outlet channels 24 are formed for removing the fluid from the working space 22, through which the space 22 is connected with the atmosphere.

Fig. 5 shows an embodiment of the vibrator, in which links, which are intended to connect the foundation 25 of the vibrator to a working platform 26, are elastic and have the shape of a spring suspension member 27. This helps to reduce as much as possible the tensile stresses at the connecting elements and at the same time store the energy in the spring suspension means 27, when the counteracting recoil force of the vibrator is as large as possible, and to more evenly and efficiently transmit this recoil force to the platform 26 at the times when the direction of movement the suspension member 27 supported the direction of the forces, which promotes the amplification of the vibrations of the work platform.

Fig. 5 further shows an embodiment of the vibrator, in which a cuff 28 is attached to the foundation 25 and provided with a means for limiting the stroke of the movable sealing edge of the cuff 28, which means consists of a screw 29 arranged in the foundation 25, one of which end via a flexible element is connected to the elastic edge of the cuff 28 and the other end of which is connected to, for example, a flexible connecting link 30 for remote control. The stroke limiter 29 contributes to a smoother vibrator function and makes it possible to remotely influence the operating condition of the vibrator, ie to remotely influence the frequency and energy of the single stroke of the vibrator. This is achieved by later or sooner removing the cuff 28 from a striker 31 and by forming an outlet channel which connects a working space 32 with the surrounding medium, thus making it possible to increase or decrease the acceleration distance of the striker 31 under the action of the fluid pressure in the workroom 32.

In order for the vibrator to be able to work more evenly, it is desirable that the impact body 31, in its reciprocating movement, is less skewed in a plane parallel to the foundation 25 or to the work platform 26, and is prevented from being displaced laterally in the same plane.

For this purpose, it is suitable that the impactor 31 is connected to the foundation 25 or the working platform 26 by means of connecting links, which are intended to limit the movement of the impactor in the plane parallel to the foundation 25 or the platform 26. Fig. 5 shows a possible embodiment of the vibrator in such an embodiment, where the impact body 31 is connected to the foundation 25 by means of a flexible or elastic plate 33 which functions as a flexible hinge member. In this embodiment, the striker 31 can move like a pendulum, so it is desirable that the foundation 25 be inclined towards the work platform 26 at an angle equal to the angle of rotation of the striker 31. However, this is not necessary, since the impactor 31 is movable a short distance, in which case the vibrator works safely with the impactor so suspended and with the foundation 25 arranged in parallel with the working platform 26. Fig. 6 shows the same vibrator (in Fig. 6). a plan view) with the work platform removed. Fig. 6 illustrates a possible embodiment of the elastic or resilient plate 33 and for its connection to the impact body 31 and the foundation 25. Instead of the plate 33, flexible wires can also be used. The impactor can, for example, be suspended from a rope or ropes. These embodiments are convenient when the vibrator in the working position is inclined towards the horizon, in which case said connecting links are operative under tensile stress conditions. If the vibrator can be arranged at any, not predetermined angle or if its position in the space must be changed during the work process, the impact body is suitably connected to a foundation 34 or a work platform 35 by means of a flat guide member or double link pieces 36, for example as shown in fig. 7. These can operate under both tensile and compressive stress conditions.

Fig. 7 shows an embodiment of a cuff 37 with an element constructed in the form of a leaf spring 38 for forcibly returning the elastic sealing edge 39 of the cuff 37 to the initial position. The spring 38 is attached to the foundation 34 and connected to the sealing edge 39 of the cuff 37 so that in its free state it strives to press the edge 39 against the foundation 34. The compressive force of the spring 38 should be chosen so that the spring 38 during the period when a striker 40 moves forward until an outlet channel is formed between the body 40 and the edge 39, cannot move the edge 39 away from the sealing surface of the body 40, against which it is pressed by the fluid pressure in a working space 41, which in other words means that the spring 38 does not earlier than at the desired time can interrupt the hermetic sealing of the workroom 41. The sleeve 37 can return to the initial position by means of various suitable means and in various possible ways, which make it possible to effectively return the edge 39 to the initial position not only over a portion thereof, but also over several portions or over the entire sealing perimeter of the workroom 41. This can be achieved, for example, by arranging the spring 38 over the entire length of the elastic edge 39 of the cuff 37 or arranging it at the top or bottom or incorporating it in the cuff 37. Such a constructive design makes the function of the vibrator more even, especially when the vibrator is driven by a liquid liquid medium. In order to make the operation of the vibrator more economical, it is suitable that a valve device is arranged at the inlet side of the fluid to the working space 41 or to interrupt the fluid supply to it during the time when the outlet fluid is diverted from the space 41 to the surrounding medium, as shown by Fig. 7. In the embodiment shown in Fig. 7, a spring-loaded valve 42 is provided with a rod '455 ÛBÛ 43, which is arranged to cooperate with the impact body 40 in its lower limit position, i.e. at the end of its return. The impactor 40 thus opens and closes the valve 42 at the same time as it performs a reciprocating movement, which makes it possible to interrupt the supply of the fluid from the fluid source to the space 41 to the space 41 during the expiration time of the effluent fluid from the working space 41, which means that the effluent fluid is not unnecessarily diverted to the surrounding medium. In this case, the vibrator works more economically, with a greater efficiency and, which is of great importance, more evenly in particular when it is driven by a liquid fluid.

Fig. 8 shows an embodiment of the vibrator, in which a working space is formed by a cuff 44 arranged between a striking body 45 and a working platform 46, while a spring 47 for returning the striking body 45 to the initial position is arranged between the body 45 and a foundation 48, which is arranged to press the body 45 against the platform 46. In this embodiment the foundation 48 is attached to the working platform 46, while the fluid is supplied to the working space via a channel 49 accommodated in the platform 46. This design is advantageous when operating conditions of the vibrator must provide an effective impact stress in the direction of the foundation 48.

Fig. 9 shows a vibrator, in which a working space 50 is also formed between a striking body 51 and a working platform 52, while the striking body 51 is connected to the platform 52 by means of an elastic suspension device in the form of, for example, springs 53, which are arranged to press the body 51 against the work platform 52. Such a design makes the construction of the vibrator somewhat simpler.

The vibrator shown in Figs. 1 and 2 operates in the following manner.

The initial position is considered to be a position shown in Fig. 1, in which the impact body 5 is in its lower limit position, while the cuff 3 attached thereto is in the compressed state, the elastic sealing edge 7 of the cuff 3 being pressed against the surface 8 of the foundation 1 After the vibrator is started, the fluid begins to enter the working space 4 via the pipeline 11 and the throttle channel 10 under pressure, where the pressure builds up. Under the action of the pressure in the space 4, the cuff 3 hermetically closes the working space 4, At the same time as the impact body 5 rapidly begins to move upwards and thereby performs its stroke forward and over the end portion of its range strikes the work platform 2. 455 050 16 About the elastic liner 13 is missing, the stroke is "stiffer". If the liner 13 is arranged, as shown in Figs. 1 and 2, the stroke is damped somewhat, whereby the percussion effect is extended in the meantime. Before the stroke is performed, the cuff 3, which is to be carried by the percussion body 5, moves away from the foundation 1, which results in its elastic edge 7 at at least one place moving away from the surface 8 of the foundation 1, whereby the outlet channel 9 ( Fig. 2) is formed between them, through which channel the effluent fluid under the action of pressure begins to be diverted to the surrounding medium. The pressure in the working space 4 is made lower and drops to zero, which is promoted by the elastic properties of the cuff, which act so that the edge 7 tends to move to the initial position, ie to be pressed against the impact body 5, thereby making the outlet channel 9 cross-sectional area larger. The pressurized fluid, which in this case flows into the working space 4 via the throttling channel 10, cannot cause a considerable overpressure in the working space 4 as a result of the hermetic seal of the latter being disturbed. After the impact body 5 has hit the work platform 2, it begins to move in the direction of return, ie downwards, through the recoil force from this and through its gravity. After the cuff 3, which is carried by the percussion body 5, has been brought into contact with the foundation 1 and its elastic edge 7 has been pressed against the surface 8 of the foundation 1 and thereby hermetically sealed the working space 4, the pressure in the space 4 begins to increase. The impactor 5 completely consumes its energy at this time and stops under the action of the pressure in the working space 4, after which it under the action of the pressure in the space 4 begins to move upwards (ie in the forward direction) and the work process is repeated.

If the impactor 5 is connected to the foundation 1 by means of the springs 12, which are intended to press the body 5 against the foundation 1, it moves faster in the return direction, in which case the frequency of the vibrator is made higher. To prevent the energy of the individual blows from decreasing, the active area of the workroom, which can be considered practically equal to the area delimited by the contact line of the side surface of the cuff 3 with the foundation 1, must be increased to the dimensions which compensate the force of the springs. The impact energy is directly proportional to the active surface of the working space 4, the pressure in the space 4 and the acceleration distance of the impact body 5 under the action of this pressure. In order to ensure that the impactor 5 before the impact has a low speed and a predetermined energy, it is sufficient to increase the active area of the working space 4 455 050 17 and proportionally reduce the acceleration distance of the impactor 5 under the action of the pressure in the space 4 or increase body weight 5. During the work process, the operating conditions of the vibrator, ie the frequency and energy of the single stroke of the vibrator, can be changed by changing the degree of opening of the start valve, ie by changing the degree of throttling of the fluid flowing in under pressure.

The vibrations so designed can be used very efficiently in combination with shaker feeders, as shown in Figs. 1 and 2, in which case an effective impact stress acts so that the rock mass 14 is transferred to a dynamic state and begins to move intensively along the vibrations performing working platform 2. While visually observing the movement of the rock mass 14, the operating conditions of the vibrator 14 can be changed by means of a starting device not shown in the drawing and thereby regulate the speed of movement of the rock mass 14 on the shaking platform 2.

This makes it possible to more fully load the rock mass on a transportable transport device (wagons) without running the risk that said transport device will be overloaded.

If the foundation 15 of the vibrator (Figs. 3, 4) is connected to the working platform 16 by means of the connecting links 17, for example rigid ones, as shown in Figs. 3, 4, while the spring 21 for returning the impact body 20 to the initial position is arranged between the impact body 20 and the work platform 16, the vibrator operates in a similar manner. In this embodiment, however, the opposing recoil force of the vibrator is transmitted over the connecting links 17 to the work platform 16, which helps to amplify the vibrations of the platform 16 and the material to be treated thereon, not shown in the drawing, thereby increasing the efficiency of the vibrator ( utilization rate) increases.

If the vibrator is so designed that at the end of its return the impactor 20 can be brought into contact with the filler 23 of the foundation 15, then the vibrator can be driven by compressed gas by increasing the inactive volume of the space 22 with the desired effect of stopping the impactor 20 at the end of its return stroke. The greater the impact energy, the smaller the braking pulse formed in the working space 22 at the end of the return of the impact body 20. This can be promoted by an increase in the idle volume of the workroom 22. The stroke frequency of the vibrator can thus be made twice as high, at the same time as a stroke stress can be produced in one or another (opposite) direction. 455 Û5Û 18 The cuff 18, which has a C-shaped cross-section along the contour of the workroom 22 and is provided with a series of outlet holes 19 in the sealing part of the cuff 18, functions practically in the same way as the cuff 3 shown in Figs. 18 sealing edges also have a limited deflection distance, for example by a suitable choice of the material or by using a special means for limiting the deflection distance of the edges. It should be noted that the presence of the row of outlet holes 19 results in a reduction in the effective cross section of the outlet channel 24 (Fig. 4), which is formed at the end of the forward movement of the impact body 20 between the sealing surface of the body 20 and the elastic edges of the outlet holes 19. must proportionally increase the width of the channel 24, which can be achieved by reducing the deflection distance of the sealing part of the sleeve 18 or by increasing the total working stroke length of the carcass 20, for example by increasing the * distance between the foundation 15 and the working platform 16.

If the foundation 25 (Fig. 5) is connected to the working platform 26 by means of the spring suspension member 27, as shown in Fig. 5, the reaction recoil force of the vibrator acting on the foundation 25 is transmitted to the working platform 26 without the latter being subjected to peak stresses due to these peak stresses are attenuated by the spring suspension member 27, which may be necessary in certain specific cases. In addition, the energy to be stored in the spring suspension means 27 at the times when the direction of the action of the springs on the work platform 26 coincides with the actual direction of movement of the platform 26 will effectively increase the oscillation of the work platform 26 and the material to be treated.

The vibrator shown in Fig. 5 is provided with the means 29 for limiting the stroke of the elastic edge of the cuff 28. The member 29 comprises the flexible shaft 30 for remote control, by means of which one can change the formation time of the outlet duct, which is intended to connect the working space 32 to the surrounding medium. This leads to an increase or a decrease in the distance of the impact of the impactor 31 during forward movement and consequently to an increase or decrease in the impact energy of the impactor 31. In this case, the stroke frequency changes slightly. By changing the formation time by means of the means 29 in combination with a change in the amount of fluid to be supplied via a start valve, one can within wider limits change individual kinds of energy and frequency in less dependent on each other. The embodiment of the vibrator, in which the striker 31 is connected to the foundation or the work platform by means of the flexible plate 33 (Figs. 5, 6) or the double link piece 36 (Fig. 7), functions in the same way as the embodiment described above, but the functional stability is improved by starting the interruption of the seal or the sealing of the working space with less deviation of the impactor from the predetermined distance (part) of the path of movement due to the impactor not being skewed in relation to the surface in contact with the elastic edge of the cuff .

By arranging the element 38 (Fig. 7) for forced return of the elastic sealing edge 39 of the cuff 37 to the initial position over at least a portion of the effective length of the element, the operation of the vibrator can be considerably improved. This is because the working space 41 under otherwise equal conditions will be hermetically sealed by the cuff 37 somewhat later, in which case the impactor 40 moves in the return direction a slightly greater distance. This results in the distance for the forward or lateral movement of the carcass 40 being made equally much under the action of the pressure from the side of the working space 41 under the action of the pressure. This in turn leads to an increase in single types of energy practically without an increase in the time required to perform the entire work cycle, and consequently to an increase in the stroke effect of the vibrator without the vibrator's other parameters, for example outer dimensions, weight etc. are changed.

Use of the valve device 42 for supply and interruption of the supply of the pressurized fluid to the working space 41, respectively, as shown in Fig. 7, makes the operation of the vibrator more economical and improves its dynamic properties. This contributes partly to the fluid not being diverted unproductively to the surrounding medium when the hermetic seal 41 of the work space is interrupted, and partly to reducing a harmful, premature braking pulse which occurs in the work space 41 at the end of the return stroke of the carcass 40, which increases the return distance of the body 40 and consequently the distance of its forward motion, while at the same time increasing single kinds of energy and the impact effect of the vibrator.

The vibrator shown in Fig. 8 operates in the same way as the vibrator according to Figs. 3, 4 except that the active shock load is applied to the foundation 48 and is directed towards it. wherein it is transmitted 455 050 to the work platform 46 by means of the connecting links connecting the platform 46 to the foundation 48. the vibrator according to Fig. 9 functions in exactly the same way as the embodiment shown in Fig. 8.

It should be noted that all embodiments described with reference to the accompanying drawings only represent possible, in some cases preferred, embodiments. Other embodiments can be used with regard to the shape, dimensions and position of separate structural parts and their elements. The parts and elements shown in the drawings can, for example, be replaced by equivalent ones. In addition, one can change the position of separate parts and their elements and use separate elements of the proposed vibrator independently of each other without therefore falling outside the scope of the invention.

Life-size models of the vibrator according to the invention have been produced, which are subjected to comprehensive testing when transporting bulk material by means of shaft transport devices. The test carried out has shown that the vibrator proposed according to the invention works evenly and functionally under arbitrary operating conditions in humid, water-rich, dusted and abrasive media even if a large amount of foreign inclusions, such as rust and sand particles, are present in the liquid medium, which is to be supplied under pressure. The impact load of the shaking platform with low movement speeds of the impact body before the impact has proven to be more efficient, at the same time as the efficiency of the vibrator is made larger and the bulk material moves more evenly on the shaking transport device. No deterioration of the other properties of the vibrator was detected compared with the known vibrators of the type mentioned.

Claims (8)

L) 455 050 Patent claims A vibrator intended to be driven by a pressurized medium in order to transmit vibrations to a working platform (2) with a material (14) to be treated thereon, which vibrator comprises a foundation (1) with a arranged at the side of the work platform (2), a working space (4) forming an elastic meme (3) which is built in the form of a closed ring and provided with at least one outlet hole (6) with an elastic edge (7), which cuff is intended to perform oscillating movements under the action of the pressurized medium and to impart vibrations to the work platform (2), characterized in that an impact body (S) is arranged on the side of the sleeve (3) facing the work platform (2), which is intended to cooperate with the work platform (2), when the cuff (3) performs oscillating movements under the action of the pressurized medium, and to impart shock vibrations to the work platform (2). A vibrator according to claim 1, characterized in that the weight of the impact body (5) exceeds the elastic deformation force of the cuff. Vibrator according to claim 1 or 2, characterized in that the impactor (5) is connected to the foundation (1) by means of at least one elastic element, which causes the impactor (5) to return quickly to the initial position. Vibrator according to one of Claims 1 to 3, characterized in that a foundation (15) is attached to a work platform (16). Vibrator according to one of Claims 1 to 4, characterized in that a striker (40, 31) is connected to a working platform (35) or a foundation (25) by means of connecting links, which are intended to limit the striker (40, 31). ) movement in a plane parallel to the work platform (35, 26). Vibrator according to one of Claims 1 to 5, characterized in that the cuff (3) is attached to the impactor (5). 455 050 2% 7. A vibrator according to any one of claims 1 - 6, characterized in that the elastic edge of the outlet hole of the cuff is in at least one portion provided with an element for forced return thereof to the initial position. A vibrator according to any one of claims 1 to 7, characterized in that a working space (41) is provided with a valve device arranged at its inlet, through which the pressurized medium is supplied to the working space (41) and the supply of said medium to the room (41) is interrupted when medium is diverted from the workroom (41) to the environment.