RU2567250C2 - Vibrator for sieving and feed of material - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to mechanical vibration process, particularly, to miner equipped with two vibratory devices configured for two devices, i.e. vibrating sieve or feeder. Vibratory device incorporates one shaft and can change the direction of motion. It comprises vibratory box, lower support plate, vibratory spring and vibratory shaft mounted at vibratory box. Vibratory spring is arranged between vibratory box and lower support plate. Multiple sets of inclined rod assemblies are arranged on both sides of vibratory box to confine the motion part. Every set of rod assemblies includes two rod assemblies to confine the motion part arranged in symmetry on both sides of vibratory box. Note here that both ends of every rod assembly are articulated with vibratory box and lower support plate.

EFFECT: higher efficiency of screening and output.

13 cl, 16 dwg

Description

The present invention relates to the field of mechanical vibration technology and, in particular, to a mining machine with a vibrating device arrangement for two vibrating screen devices or a feeding unit, and more particularly, to a vibrating device for screening and feeding material made with one shaft and with the possibility of trajectory changes.

The existing mechanical vibration devices of the conventional art can be divided into three categories, circular motion, linear motion and elliptical motion based on the motion path. Mechanical vibration devices of the conventional art can be divided into three types, with one shaft, with two shafts and with three shafts based on the design of the vibration device. Various designs of the vibrating device provide trajectories of motion, as described below.

1. The trajectory of circular motion is implemented using a vibrating device.

2. The linear motion trajectory is realized using a vibrating device with two shafts.

3. The trajectory of the elliptical movement is realized using a vibrating device with three shafts.

Several improvements and innovations have been made, and several invention patents and utility model patents are known. For example, patent CN 200920213889.6 entitled "Single-shaft vibrating motion track vibration exciter for mechanical vibrating screen"; patent CN 200310119021.7, entitled "Double-shaft inertial vibration exciter"; CN patent 200920213200.X entitled "Triple-shaft vibrator of elliptical vibrating screen". Although there are improvements in the patents, they do not go beyond rethinking the combination with one shaft or several shafts.

With different paths of movement, the performance of the vibrating device is also different. So, the performance of the vibration devices is described as follows.

1. Using a vibrating device with one shaft receive a trajectory of circular motion. The advantages of a single-shaft vibrating device are that said vibrating device not only has a component of the vibrating force in the normal direction, but also has a component of the vibrating force in the tangential direction, and critical materials cannot easily block the openings of the sieve cells. The disadvantages of a single-shaft vibrating device are that when the vibrating device interacts with a spring located in the vibrating box when moving, the materials can only move up and down during sifting, but cannot move horizontally for feeding, since the horizontal component of the force is extremely small. Therefore, all commercially available single-shaft devices provide an inclined installation using gravity to obtain horizontal movement for feeding. Due to the inclined installation, the materials descend too quickly and are not completely sifted. Thus, screening is unsatisfactory.

2. Using a vibrating device with two shafts, a linear motion path is obtained. An advantage of a vibrating device with two shafts is that it is possible to regulate the existing guiding angle of vibration in the range from 0 ° to 90 ° by changing the phase angles of the eccentrics of the two vibrating shafts, typically angles in the range of 30 ° -60 ° are chosen for use. Accordingly, the materials can be moved up and down for vertical screening and can also be moved horizontally for transportation, so that in use a vibrating device with two shafts can be mounted horizontally. Due to the horizontal installation, the materials are sifted completely and the sieving performance is remarkable. A disadvantage of a two-shaft vibrating device is that due to linear motion, the two-shaft vibrating device can vibrate in the normal direction, but cannot vibrate in the tangential direction, so that critical materials can easily block the sieve cells and the screening performance is reduced .

3. Using a vibrating device with three shafts, a trajectory of elliptical motion is obtained. The advantages of a three-shaft vibrating device combine the advantages of circular motion and linear motion. A vibrating device with three shafts can be installed horizontally during operation, and critical materials cannot easily block the openings of the cells. However, the disadvantages of the vibration device with three shafts are that the structure is complex, the manufacturing cost is high, and the power consumption is significant. When the vibration device with three shafts, as well as the vibration device with two shafts are adjusted in the direction angle, the vibration device should be opened to remove the gear mechanism, i.e. regulation of the phase difference of the eccentrics of the vibrating shaft, which is time-consuming. Users can easily make the mistake of adjusting the phase difference of the cam shaft of the vibrating shaft.

To summarize, if you use a vibration device with one shaft of conventional technology, the design is simple, but the vibration device with one shaft should be installed obliquely, while the sifting performance is significantly reduced, and the height difference between the upper end and lower end, established using a vibration box, is significant, which requires an increased working volume and increases the cost of installation. If you use a vibration device with several shafts of conventional technology, the vibration device with several shafts can be installed horizontally and the performance of the vibration device with several shafts is improved, but the material consumption for the mechanism is significant, the manufacturing complexity is high, the cost of operation is high, and the guiding angle of vibration not easy to regulate.

The biggest drawback of conventional technology is the ability to implement a vibration device with only one motion path, and the inability to switch the device to other motion paths.

The objective of the present invention is to provide a vibration device with one shaft with the ability to change the trajectory of movement, which has a simple structure and low cost. A single-shaft vibration device with the ability to change the motion path can create several motion paths. The vibration device with one shaft with the ability to change the trajectory is adapted to meet the requirements of various operating conditions. The single-shaft vibrating device with the ability to change the motion path can be easily adjusted, the vibration excitation efficiency is high, and the sieving performance is remarkable. The technical problems that exist in the ordinary state of the art have been resolved, where different vibration devices are selected for the various motion paths required, the design is complex, and the adjustment is not easy.

The technical problems mentioned above are solved using the technical schemes of the present invention, which are described below.

According to a first aspect of the present invention, there is provided a vibration device for sifting and feeding material, made with one shaft and with the possibility of changing the trajectory of movement and comprising: a vibration box, a lower base plate, a vibration spring, a vibration shaft; wherein the vibration shaft is mounted on the vibration box, and the vibration spring is installed between the vibration box and the lower base plate. On both sides of the vibration box there are many groups of rod assemblies that limit the trajectory and are located obliquely. Each group of rod nodes that limit the path of movement contains two rod nodes that limit the path of movement, which are located symmetrically on both sides of the vibration box, and both ends of each rod node that limits the path of motion are pivotally attached to the vibration box and the lower base plate.

A rod assembly restricting the path of movement is a major component of the construction of the present invention. The rod assembly restricting the motion path determines the motion path of the force exciting the vibration, and the rod limiting the motion path is the rod defining the motion path.

The structural features of the present invention are described below.

(1) A single shaft is used as a vibration source.

(2) An additional rod mechanism is installed to limit the trajectory of movement and located obliquely and symmetrically.

(3) The vibration box does not require inclined installation and can be installed horizontally for operation.

(4) The control mechanism of the guide angle of vibration excitation is installed externally.

Functional features of the present invention are described below.

(1) The vibration box can be installed horizontally for installation and operation with the design of a vibration device with one shaft, i.e. the circular motion path has a guiding angle of vibration.

(2) Three motion paths when a vibration is excited, a circular motion path, a linear motion path and an elliptical motion path can be included in a single device.

(3) The guiding angle of vibration can be adjusted externally, visually and simply.

The basic technology of the present invention is described below.

A constructive solution of a combined vibrating device with one shaft and a rod assembly, limiting the trajectory of movement, is used. The function of three motion paths, circular, linear and elliptical can be implemented in one device, and three motion paths can be easily switched. The design solution replaces the conventional technique, which requires the use of, respectively, one shaft, two shafts and three shafts to implement the functions mentioned above. Thus, the functions and efficiency of the vibrating device are greatly increased.

The present invention has a vibration excitation function of three motion paths, circular, linear and elliptical, and the vibration excitation force function can easily be switched in one device. The principles of mechanization are described below.

The rod node, limiting the trajectory of movement, moves in two dividing movements under the action of the circular inertial force of the eccentric shaft, which are described below.

(1) In the axial direction of the rod limiting the trajectory, the rod assembly limiting the trajectory moves a short distance of sliding and linear motion. The trajectory is a straight line. The length of movement is determined by the sliding interval, which is set in the rod, restricting the trajectory of movement.

(2) The rod assembly restricting the path of movement moves a short distance when swinging and moving along an arc relative to the center of the circle, which is the top point of the lever arm of the rod that restricts the path of motion, and the radius is a length segment from the bottom point of the lever arm to the top point lever support, and the trajectory is an arcuate line. Since the arcuate line is very short, the arcuate line can be approximated as a straight line. The length of the arcuate line is determined by the characteristic of the spring, i.e. elasticity.

The combination of sliding and linear motion, and rocking and moving along an arc, are presented in circular, linear and elliptical trajectories of motion, to create several different vibrational paths that excite vibration forces.

The long axis of the ellipse of the trajectory of movement is determined by the weight of the vibration box and the characteristic of the spring, i.e. elastic interval, which is a constant value. The short axis of the ellipse of the trajectory of movement is determined by the interval of regulation of the sliding of the rod, limiting the path of movement, while the interval of sliding can be adjusted, and can usually be adjusted in the range of 0-20 mm. The range for adjusting the slip interval is specifically described below.

1. When the interval is 0 mm, the motion path is shown as a straight line, but in fact the motion path is an arcuate line.

2. When the slip interval is equal to the length of the arc, the path is shown as a circle.

3. When the slip interval is not equal to the length of the arc, the path is shown as an ellipse.

Significant effects of the present invention are described below.

1. By adjusting the sliding interval of the rod, limiting the trajectory of motion, it is possible to include various motion paths, circular, linear and elliptical, which can be easily implemented in one device. The functions are similar to the functions that a vibrating device with one shaft, a vibrating device with two shafts and a vibrating device with three shafts, independently create a circular motion path, a linear motion path, and an elliptical motion path.

2. If you change the range of angles of inclination of the rod, restricting the path of movement, the guiding angle of vibration can be easily adjusted.

3. The aforementioned functions of the present invention are realized under the conditions of a single-shaft vibrating device, as described below.

A single-shaft vibration device of the conventional art can only generate a vibrational force to produce a circular path, and a vibrational force for a circular path does not have a guiding angle of vibration. Materials can only move in screening up and down, but cannot move in the horizontal feed direction. Therefore, a vibration device with a single shaft of conventional technology can only be operated when the vibration box is installed obliquely, and gravity is used to obtain horizontal movement of the material feed.

The present invention has a guiding angle of vibration due to the use of a design solution for combining a vibrating device with one shaft and a rod restricting the motion path in the conditions of a vibrating device with one shaft, regardless of the motion path. The limitation is that the vibration device with one shaft is used with the vibration box mounted obliquely, removed. The vibration device with one shaft implements the installation and use of the vibration box in a horizontal position.

In other words, for a single-shaft vibrating device, the conventional single-shaft vibrating device can be used with a vibrating box mounted obliquely, but the single-shaft vibrating device of the present invention can be used with a horizontal vibrating box so that the materials can be sifted more fully. and screening performance is higher.

Preferably, the groups of rod assemblies restricting the trajectory of movement are located symmetrically along the longitudinal line where the fixed axis of the vibrating shaft is located. When the number in the group of rods limiting the trajectory of motion is an odd number, in the rod nodes limiting the trajectory of motion located on one side of the vibrating box, the upper end of the hinged position of the rod nodes limiting the trajectory of motion is set in the middle position on the longitudinal line where fixed axis of the vibration shaft. Other rod assemblies restricting the trajectory of movement are located symmetrically on the longitudinal line, where the fixed axis of the vibration shaft is located.

In a side view in the group of rod assemblies that limit the trajectory, the number of which in the group is an odd number, the upper end of the hinge position located in the middle group and the longitudinal line where the fixed axis of the vibration shaft is located are located on one straight line. When only one group of pivot nodes restricting the path is created, the pivot node limiting the path of motion and the articulated shaft are mounted on the longitudinal line where the fixed axis of the vibrating shaft is located. For a circular trajectory, a single-shaft vibrating device in the conventional art continues to move in equilibrium before and after a vibrating box with a longitudinal line, where the fixed axial output of the vibrating shaft is located as a boundary, when limited movement passes beyond the longitudinal line, the amplitude of the front of the vibrating box and the back of the vibration box is not symmetrical, vibrational balance cannot be guaranteed. Thus, the rod assembly restricting the trajectory of motion is installed as the structure mentioned above, so that the vibration balance can be satisfactorily guaranteed.

Alternatively, when the number in the group of rod nodes limiting the path of movement is an even number, rod nodes limiting the path of movement located on one side of the vibration box are located symmetrically in the center of the longitudinal line where the fixed axis of the vibration shaft is located.

The path-limiting mechanisms are set in pairs and are located symmetrically on both sides of the vibration box, in particular, are located symmetrically on both sides of the vibration box, the positions of the two ends of the vibration shaft, and the bar mechanisms limiting the path of movement located on the same side of the vibration box are symmetrically located in such a way that the vibrational balance is further increased.

Preferably, the angle formed by the rod assembly restricting the path of movement and the horizontal plane in which the vibration box is located is an acute angle. The angle is in the range 30 ° -60 °. In total, the acute angle and the guiding angle of vibration are 90 °. The letter β denotes the guiding angle of the vibrations, and the letter α denotes the acute angle. The ratio between β and α is expressed as β = 90 ° -α.

A positive effect is obtained, described below.

In the conventional art, the linear motion path and the elliptical motion path have such a vibration angle that the vibration box of the vibrating device with one shaft is applied horizontally, but the circular motion path does not have a vibration angle, so that the vibration box must be set obliquely to obtain horizontal force feed by gravity. However, in the present invention, regardless of the path of linear motion, the path of elliptical motion or the path of circular motion, the vibration device with one shaft can be installed horizontally for operation, and the most efficient operation.

The angle β is determined by the angle α. Therefore, for simple regulation of the angle α of the rod nodes limiting the trajectory of motion, an arc-shaped regulator is installed. Theoretically, the angle α can be adjusted in the range from 0 ° to 90 °; usually a suitable range for adjusting the angle α is from 30 ° to 60 °.

The design of the rod node, restricting the trajectory of movement, have various shapes. According to different trajectories of movement and different requirements of working conditions, it is possible to develop several structural forms, which are described below.

Preferably, the rod assembly restricting the path of movement comprises an arcuate regulator and a rod limiting the path of movement. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. The first end of the rod, limiting the trajectory of motion, is pivotally fixed in the hole of the arcuate groove. The second end of the rod, limiting the trajectory of motion, is pivotally mounted on a vibration box. The length of the rod restricting the motion path is not adjustable, and the resulting motion path is a linear motion path.

The trajectory of the vibratory device with the design of the rod node, limiting the trajectory of motion, is the trajectory of linear motion. The advantages of the design of the rod node, restricting the path of movement, are described below.

The design of the rod assembly restricting the trajectory is simple for maintenance. The vibration device is particularly suitable for restricting a single linear motion path and requiring a small investment.

Alternatively, the rod assembly restricting the path of movement comprises an arcuate regulator and a rod limiting the path of motion. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. The rod limiting the path of movement includes an upper rod limiting the path of movement, and a lower rod limiting the path of movement. The threads are made on the outer peripheral surfaces of the upper rod restricting the motion path and the lower rod limiting the motion path, and the threads of the upper rod limiting the motion path and the thread of the lower rod limiting the motion path have opposite directions. A threaded sleeve is installed to connect the upper rod, limiting the path of movement, and the lower rod, limiting the path of movement. The first end of the upper rod, limiting the trajectory of motion, is pivotally mounted on a vibration box. The second end of the upper rod, limiting the trajectory of movement, is placed in a threaded sleeve. The first end of the lower rod, limiting the path of movement, is pivotally fixed in the hole of the arcuate groove, and the second end of the lower rod, limiting the path of movement, is placed in the threaded sleeve.

The rod limiting the trajectory of motion is fixed in the threaded sleeve, and the threaded sleeve moves in a small offset along the arc. The design of the rod assembly, limiting the trajectory of movement, limits the trajectory of the circular motion of the vibrating device with one shaft of conventional technology, which changes the trajectory of circular motion to the trajectory of linear motion. Therefore, materials can not only move up and down with vertical screening, but can also move with horizontal feeding in such a way that the materials can be screened more fully, the screening performance becomes closer to ideal, the limiting condition for installing an inclined vibration box for a vibrating device with one shaft is removed, and vibration box can be installed horizontally.

The coordinates of the rod limiting the path of movement are defined by a threaded sleeve on its thread, so that the length of the rod limiting the path of movement can be adjusted. When installing a rod assembly restricting the motion path in the factory, any desired length of the rod limiting the motion path can be easily set in the size range of the rod assembly restricting the motion path.

The functioning of the structural scheme is the same as the previous structural schemes, the difference lies in the ability to adjust the length of the rod, restricting the trajectory of movement. When the compression elasticity of the spring changes, the length of the rod, limiting the trajectory of movement, can be slightly adjusted, ensuring the operation of the device in the best conditions.

Alternatively, the rod assembly restricting the path of movement comprises an arcuate regulator and a rod limiting the path of motion. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. The rod limiting the trajectory of movement contains a polished rod. The sliding sleeve is mounted on a polished stem. The sliding sleeve is pivotally mounted on the vibration box. The polished rod is pivotally fixed in the arcuate holes with a groove.

The trajectory of the vibrating device with the design of the rod node, restricting the trajectory of movement, is the trajectory of an elliptical motion. The advantages of a vibrating device with a rod assembly design restricting the path of movement are described below.

The design of the rod assembly restricting the trajectory is simple for maintenance. The vibratory device is particularly suitable for limiting the path of an elliptical motion and requiring low investment.

Alternatively, the rod assembly limiting the path of movement comprises an arcuate regulator and a rod limiting the path of motion. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. The rod limiting the trajectory of movement contains a polished rod. The screw spindle section is mounted on the first end of the polished rod, and the screw spindle section is mounted on the second end of the polished rod. The sliding sleeve is mounted on a polished stem. The diameter of the polished rod section is larger than the diameter of the screw spindle section. The length of the polished rod section is less than the length of the sliding sleeve. A combination of a lock nut and a lock nut is mounted on a section of a screw spindle mounted on the first end of the polished rod, and another combination of a lock nut and a lock nut is mounted on a section of a threaded rod mounted on the second end of the polished rod. A spring with silencing the impact sound is installed as a clutch on the sections of the rod restricting the path of movement located between the sliding clutch and the lock nuts, which are installed on both ends of the sliding clutch. The sliding sleeve is pivotally mounted on the vibration box, while the threaded rod section is pivotally mounted in the arcuate holes with a groove.

The significant beneficial effect of the vibrating device with the optimized design of the rod assembly restricting the motion path is described below.

By adjusting the sliding interval of the rod nodes, limiting the path of motion, switching between the path of circular motion, the path of linear motion and the path of elliptical motion can be easily obtained in one device, which removes the restriction on which the vibrating device has only one path of motion. Three motion paths are included in one vibration device, to meet the requirements of various operating conditions, increase the functionality of the device, and expand the scope of the device.

Alternatively, the rod assembly restricting the path of movement comprises an arcuate regulator and a rod limiting the path of motion. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. A sliding clutch is mounted as a clutch on a rod restricting the path of movement. A sliding cavity is created inside the sliding sleeve. The end with the first opening of the sliding cavity is connected to an adjustable threaded sleeve, the coordinates of which are set by the thread, and the end with the second hole of the sliding cavity is connected to an adjustable threaded rod, the coordinates of which are set by the thread. A guide channel connected to the sliding cavity is mounted inside an adjustable threaded sleeve. The rod limiting the trajectory of movement passes through the guide channel and passes into the sliding cavity. The upper locknut is installed as a coupling on the outside of the adjustable threaded coupling. The lower locknut is installed as a coupling on the outside of the adjustable threaded rod. A cushion for silencing the impact sound, the coordinates of which are set by a rod restricting the trajectory of motion, is installed in the sliding cavity. The upper end of the rod, limiting the trajectory of motion, is pivotally mounted on a vibration box. The lower end of the adjustable threaded rod is pivotally mounted on the lower base plate.

The functioning of the structural scheme is similar to the functioning of the previous structural scheme, but it is preferable to control the length of the rod, limiting the trajectory of movement. When the spring compression return function changes during installation of the setup device, or according to the work schedule, the length of the shaft limiting the trajectory of movement can be precisely controlled in order to guarantee the best working conditions of the device.

Alternatively, the rod assembly restricting the path of movement and the vibration spring are mounted on one lower base plate. The rod node, limiting the trajectory of movement, contains an arcuate guide groove made on the lower base plate. The arcuate slide rail is mounted in an arcuate guide groove. The arcuate slide rail is connected to the first end of the rod, limiting the path of movement. The second end of the rod, limiting the trajectory of motion, is connected to the vibration box by the support shaft. The first end of the vibration spring is connected to the vibration box by the support shaft. The second end of the vibration spring is fixed to the spring support. The spring support is mounted on an arcuate slide rail. Through the use of a combination of a bar restricting the path of movement and a spring in the rod assembly restricting the path of movement, the vibration box is supported not only using the spring design of conventional equipment, but also with a bar restricting the path of movement, which not only serves as a support function, but also changes the function the trajectory of a vibrating device with one shaft of conventional technology, in this way the spring has the function of exciting vibration and maintaining the application of force I, when the spring performs vibration excitation.

Preferably, the vibration spring is vertical with respect to the shaft limiting the path of movement.

A unique characteristic of the design scheme is that the rod assembly restricting the trajectory of the movement and the vibration spring are designed to be installed on one lower base plate. Significant functional characteristics of the design are described below.

1. Part of the load from the vibration box is carried by the rods restricting the trajectory, and the load carried by the spring is reduced by the rods restricting the trajectory, which does not provide other structural solutions of the rods restricting the trajectory mentioned above in the ordinary prior art.

2. The spring always remains upright during loading and operation, so that a satisfactory vibration function can be obtained and the spring's service life extended.

In the various structural solutions of the bar limiting the path of motion mentioned above, which are conventional technical solutions of the bar limiting the path of motion, the springs are all located in the vertical direction. Since the vibration-exciting force has a guiding angle, the spring is compressed laterally. After compressing the side spring for a long time, the spring becomes easily deformable, and the vibrational beneficial effect is gradually reduced. The design solution eliminates the drawback mentioned above.

Alternatively, the rod assembly restricting the path of movement comprises two arcuate regulators, two rods limiting the path of motion, an upper connecting rod and a lower connecting rod. The arcuate regulator is mounted on the lower base plate. Arcuate holes with a groove are made on an arcuate regulator. The upper ends of the two rods limiting the trajectory of motion, both are pivotally mounted on the upper connecting rod, and two hinges are located on the vibration box. The lower ends of the two rods limiting the trajectory of motion, both are connected to the lower connecting rod, and two hinges are respectively located in two arcuate holes with a groove. The rods limiting the trajectory of movement are connected with the design of the interval of sliding.

Preferably, the design of the sliding interval contains a sliding rod. The sliding cavity is located in the sliding rod. The first end of the rod, limiting the trajectory of movement, passes into the sliding cavity. A rubber silencing pad is installed in the slip cavity. An external adjustable threaded rod is mounted outside the sliding rod. The sliding rod is fastened with an external adjustable threaded rod with the upper lock nut. An internal adjustable threaded rod is mounted at the second end of the external adjustable threaded rod. The articulated end of the internal adjustable threaded rod is pivotally mounted on the upper connecting rod, which is pivotally fixed in the hole of the arcuate groove. The internal adjustable threaded rod and the external adjustable threaded rod are fixed with the lower lock nut.

A design characteristic of the circuit is described below.

A parallelogram is formed by two rods limiting the trajectory of movement, the upper connecting rod and the lower connecting rod. The advantage is that when adjusting the guiding angle of vibration, the two rods limiting the path of movement are always parallel to ensure a satisfactory vibration function.

Technical advantages of the present invention are described below.

1. The vibration box can be installed horizontally and used with the design of a vibration device with one shaft, i.e. the circular motion path has a guiding angle of vibration.

2. Different motion paths can be obtained by switching in one device.

3. The guiding angle of vibration can be adjusted externally, with visual control and simply.

The advantages of the present invention are described below.

1. The design is simplified and cost reduced. Compared to a two-shaft structure and a three-shaft structure, a single-shaft structure of the present invention saves two or three vibration shafts, bearings and gears that are expensive. The cost of manufacturing the rod assemblies restricting the path of motion of the present invention is 1 / 5-1 / 3 of the cost of the components indicated above, i.e. 20% -70% of the manufacturing cost can be saved.

2. Energy losses are reduced and the cost of operation is low. The height of the vibration shaft is significant, and the vibration shaft is operating at high speed, so that the energy loss of the vibration shaft is significant. The vibrating shaft is replaced by a rod assembly restricting the path of motion of the present invention, so that energy loss during operation can be reduced by 1 / 4-1 / 3.

The present invention provides easy installation, adjustment, and maintenance. The design of a multi-shaft vibrating device is difficult to install. Particularly difficult is the adjustment of the guide angle. 3-5 people are required for the coordinated execution of the opening of the rod assembly, restricting the trajectory of movement, removing the gear train, changing the steering angle, and setting the gear gear back. In contrast to the above, one person can adjust the guide angle quickly using the design of the arcuate groove of the present invention.

The technology of the present invention provides a simple upgrade to older devices. Older devices can be retrofitted at the job site using a vibrating screen or a feed unit of a vibrating device with one shaft of conventional equipment, suitable for a rod assembly that limits the trajectory of movement.

5. The practicality and applicability of the present invention are described below.

Groups of rod assemblies limiting the motion path of a vibrating device with one shaft with the possibility of changing the motion path can be performed as one group or several groups. The rod assembly limiting the path of movement can be designed with different designs to meet the requirements for different paths of movement and the requirements of different operating conditions.

These and other objectives, features and advantages of the present invention should become apparent from the following detailed description, claims and the accompanying drawings, in which:

FIG. 1 is a front view of a single-shaft vibrating device with the ability to change the motion path according to a preferred embodiment of the present invention;

FIG. 2 is a plan view of the vibrating device of FIG. 1 according to a preferred embodiment of the present invention;

FIG. 3 is a first structural diagram of a preferred embodiment of the present invention;

FIG. 4 is a structural diagram of a rod restricting the path of movement; FIG. 3 according to a preferred embodiment of the present invention;

FIG. 5 is a second structural diagram of a preferred embodiment of the present invention;

FIG. 6 is a third structural diagram of a preferred embodiment of the present invention;

FIG. 7 is a structural diagram of a rod restricting the path of movement; FIG. 6 according to a preferred embodiment of the present invention;

FIG. 8 is a fourth design diagram of a preferred embodiment of the present invention;

FIG. 9 is a structural diagram of a rod restricting the path of movement; FIG. 8 according to a preferred embodiment of the present invention;

FIG. 10 is a fifth structural diagram of a preferred embodiment of the present invention;

FIG. 11 is a sixth structural diagram of a preferred embodiment of the present invention;

FIG. 12 is a seventh design diagram of a preferred embodiment of the present invention;

FIG. 13 is an eighth construction diagram of a preferred embodiment of the present invention;

FIG. 14 is a diagram of a linear motion path, at m = 0, according to a preferred embodiment of the present invention;

FIG. 15 is a diagram of an elliptical motion path at m ≠ L according to a preferred embodiment of the present invention; and

FIG. 16 is a diagram of a circular motion path, at m = L, according to a preferred embodiment of the present invention.

The technical schemes and preferred embodiments of the present invention are further described in detail below with reference to the drawings.

Preferred Embodiment 1

In FIG. 1 and 2 show a vibration device with one shaft with the possibility of changing the path of movement, containing a vibration box 1, a lower support plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 are installed between four angles located between the vibration box 1 and the lower support plate 2. The vibrating shaft 3 is rotated by the electric motor 21 using the drive belt 22. The vibrating shaft 3 is an eccentric shaft.

The rod 7, limiting the path of movement, located obliquely, is installed between the vibration box 1 and the lower base plate 2. The rod, limiting the path of movement, is paired and is located symmetrically on both sides of the vibration box 1. The rod 7, limiting the path of movement, is a fixed rod, whose length is not adjustable.

The lower end of the rod 7, limiting the path of movement, and the hinge shaft of the lower base plate 2 are installed in the arcuate hole 5 with a groove, and are fixed with an adjustable nut. An arcuate hole 5 with a groove is made in the support bracket 4, and the support bracket 4 is mounted on the lower base plate 2. Since the lower end of the rod 7, limiting the path of movement, is fixed with a nut, when moving the rod, limiting the path of movement, is rotated at a lower fixed point, as in the center of the circle.

The rod 7, limiting the path of movement, is mounted vertically on the fixed axial output of the vibration shaft 3, and the upper end of the rod 7, limiting the path of movement, and the hinged shaft of the vibration box 1 are installed along the longitudinal line where the fixed axial output of the vibration shaft 3 is located. The rod 7, restricting the path of movement, and the horizontal plane in which the vibration box 1 is located, form an angle that is an acute angle. The acute angle indicated by α is 60 °. The guiding angle of vibration is designated β. The ratio between β and α is expressed as β = 90 ° -α, and the angle β is 30 °. When directed to various devices for adjusting the angle β of the direction of vibration, the rod 7, restricting the path of movement, can slide, rising at different angles in the arcuate hole 5 with a groove, and the rod 7, limiting the path of movement, is fixed with an adjustable nut.

Since the length of the rod 7, restricting the trajectory of motion, is not adjustable, the sliding interval m of the rod 7, restricting the trajectory of motion, is m = 0. In FIG. 14 the direction of movement of the vibration spring 19 of FIG. 1 is shown by an arrow; movement is swinging along an arc. The trajectory of the materials located in the vibration box 1 is a trajectory of linear motion.

Preferred Embodiment 2

Shown in FIG. 3 and 4, the vibration device with one shaft with the possibility of changing the path of movement contains a vibration box 1, a lower support plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 are installed between four angles located between the vibration box 1 and bottom base plate 2.

The rod 7, limiting the trajectory and located obliquely, is installed between the vibration box 1 and the lower base plate 2. The limiting path trajectory is paired and is located symmetrically on both sides of the vibration box 1.

The rod 7, limiting the path of movement, is made in the form of a threaded rod, two sections of which are separated and the two threads have opposite directions, the sections are the upper rod 71, limiting the path, and the lower rod 72, limiting the path. The upper rod 71, limiting the path of motion, is connected to the lower rod 72, limiting the path of motion, by a threaded sleeve 6. The free end of the upper rod 71, limiting the path of motion, is pivotally mounted on the vibration box 1. The free end of the lower rod 72, which restricts the path of movement, is pivotally mounted on the lower base plate 2. In the direction of the various vibration boxes, the length of the rod 7, limiting the path of movement, can be adjusted by adjusting the length between the upper rod 71, limiting the path of movement, and the lower rod 72, limiting the path of movement. After adjusting the length of the rod 7, limiting the path, the length of the rod 7, limiting the path, does not change when the rod 7, limiting the path, vibrates, so that the slip interval m of the rod 7, limiting the path, m = 0, and the path in the vibration box 1 is shown in FIG. fourteen.

The lower end of the lower rod 72, restricting the path of movement, and the hinge shaft of the lower base plate 2 are installed in the arcuate hole 5 with a groove and are fixed with an adjustable nut. An arcuate hole 5 with a groove is made in the support bracket 4, and the support bracket 4 is mounted on the lower base plate 2.

The rod 7, limiting the path of movement, is mounted vertically on the fixed axial output of the vibration shaft 3, and the upper end of the rod 7, limiting the path of movement, and the hinged shaft of the vibration box 1 are installed in the longitudinal line where the fixed axial output of the vibration shaft 3 is located. The angle formed by the rod 7, restricting the trajectory of movement, and the horizontal plane in which the vibration box 1 is located, is an acute angle. The acute angle indicated by α is 45 °. The guiding angle of vibration is designated β. The ratio between β and α is expressed as β = 90 ° -α, and the angle β is 45 °.

Preferred Embodiment 3

Shown in FIG. 5, a vibration device with one shaft with the possibility of changing the path of movement comprises a vibration box 1, a lower support plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. Vibration springs 19 are installed between four angles located between the vibration box 1 and the lower support plate 2. The rod 7, limiting the path of movement, is a smooth rod. The upper end of the rod 7, limiting the path of movement, is installed in the sliding sleeve 8, and the sliding sleeve 8 is pivotally mounted on the vibration box 1. The lower end of the rod 7, limiting the path of movement, is pivotally mounted on the lower base plate 2. The rod 7, limiting the path of movement, can move in the sliding sleeve 8, and the sliding interval m of the rod 7, restricting the path of movement, can be adjusted. In FIG. 15 shows that when m = L, the motion path is a circular motion path. In FIG. 16 shows that when m ≠ L, the path of motion is the path of elliptical motion. The coordinates of the rod 7, limiting the path of movement, are set using the sliding sleeve 8, so that the length of the rod 7, limiting the path of movement, is not fixed. When installing the rod 7, restricting the path of movement, in the factory, you can easily satisfy any requirements for the length of the rod 7, limiting the path of movement.

The remaining parts are the same as shown in the preferred embodiment 2.

Preferred 4 embodiment of the invention

Shown in FIG. 6 and 7, the vibration device with one shaft with the possibility of changing the path of movement comprises a vibration box 1, a lower base plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 are installed between four angles located between the vibration box 1 and bottom base plate 2.

The upper end of the rod 7, limiting the path of movement, is mounted on the sliding sleeve 8, and the sliding sleeve 8 is pivotally mounted on the vibration box 1. The lower end of the rod 7, limiting the path of movement, is pivotally mounted on the lower base plate 2.

Section 20 of the polished rod is mounted on the rod 7, restricting the trajectory of movement. Both ends of the polished rod section 20 have male threaded sections. The diameter of the polished rod section 20 is larger than the diameter of the threaded rod section. The length of the polished rod section 20 is less than the length of the sliding sleeve 8. The polished rod section 20 is installed in the sliding sleeve 8. The combination of the lock nut 9 and the lock nut 10 are mounted respectively on the threaded rod section of both ends of the polished rod section 20. A spring with a shock absorber 11 is installed as a clutch, respectively, on the section of the rod 7, restricting the path of movement, between the sliding sleeve 8 and the lock nut 9 on both sides of the sliding sleeve 8. When the rod 7, restricting the path of movement, moves, the sliding sleeve 8 is fixed, and the rod 7, limiting the trajectory of movement, moves in the sliding sleeve 8 compressing or stretching the muffled spring 11, an interval m of sliding is formed. As shown in FIG. 15, when m = L, the motion path is a circular motion path. As shown in FIG. 16, when m ≠ L, the path of motion is the path of elliptical motion. The coordinates of the rod 7, limiting the path of movement, are set using the sliding sleeve 8, so that the length of the rod 7, limiting the path of movement, is not fixed. When installing the rod 7, restricting the path of movement, in the factory, you can easily satisfy any requirements for the length of the rod 7, limiting the path of movement.

The remaining parts are the same as shown in the preferred embodiment 3.

Preferred 5 embodiment of the invention

Shown in FIG. 8 and 9, the vibration device with one shaft with the possibility of changing the path of movement contains a vibration box 1, a lower support plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 are installed between four angles located between the vibration box 1 and the lower base plate 2. The rod node, restricting the trajectory of motion and located obliquely, is installed between the vibration box 1 and the lower base plate 2.

The rod node, limiting the path of movement, contains a rod 7, limiting the path of movement. The kinematic pair consists of a rod 7, limiting the trajectory of movement, and a sliding guide rod 32, which can elastically move. The sliding guide rod 32 is mounted as a sleeve in an external adjustable threaded rod 34. The sliding interval m can be adjusted by moving and returning the thread. In FIG. 15, when m = L, the motion path is a circular motion path. In FIG. 16, when m ≠ L, the path of motion is the path of elliptical motion. The coordinates of the rod 7, limiting the path of movement, are set using the sliding sleeve 8, so that the length of the rod 7, limiting the path of movement, is not fixed. When installing the rod 7, restricting the path of movement, in the factory, you can easily meet any requirements for the length of the rod 7, limiting the path of movement. The internal adjustable threaded rod 37 is connected to the lower thread of the external adjustable threaded rod 34. The entire length of the telescopic rod 31 can be adjusted by screwing and unscrewing to obtain the best installation and adjustment position. Before adjusting the total length of the telescopic rod 31, the upper lock nut 33 and the lower lock nut 36 must be released. After adjusting the total length of the telescopic rod, the upper lock nut 33 and the lower lock nut 36 are fixed. Pillow 35 silencing shock performs the function of silencing the sound of the shock.

The remaining parts are the same as shown in the preferred embodiment 3.

Preferred Embodiment 6

Shown in FIG. 10, a vibration device with one shaft with the possibility of changing the path of movement comprises a vibration box 1, a lower support plate 2, a vibration spring 19, and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 are installed between four angles located between the vibration box 1 and lower base plate 2.

Three groups of rod assemblies restricting the path of movement are mounted on vibration box 1. Each group of rod assemblies limiting the path of movement is located symmetrically on both sides of vibration box 1. Shown in FIG. 3, the rod assembly restricting the path of movement comprises a rod 7 limiting the path of motion and a sliding sleeve 8. The upper end of the rod 7 limiting the path of movement is installed in the sliding sleeve 8. The sliding sleeve 8 is pivotally mounted on the vibration box 1.

The lower end of the rod limiting the path of movement is pivotally mounted on the lower base plate 2. The supporting bracket 4 is mounted on the lower base plate 2. An arcuate hole 5 with a groove is arranged in the supporting bracket 4. The lower end of the rod 7, limiting the path of movement, and the hinge shaft of the lower the base plate 2 are installed in the arcuate hole 5 with a groove, and are fixed with an adjustable nut 51.

The rods 7, limiting the trajectory of movement, the entire group are located obliquely, and the rods 7, limiting the trajectory of movement, are installed vertically to a fixed axial output of the vibration shaft 3.

The sliding clutch 8 of the mechanism limiting the path of movement, in the middle position of the mechanisms limiting the path of movement located on one side of the vibration box 1, and the hinge shaft of the vibration box 1 are installed along the longitudinal line of the fixed axis of the vibration shaft 3. Another rod 7, limiting the path of movement , is located symmetrically in the longitudinal line of the fixed axis of the vibration shaft 3.

The rod 7, restricting the trajectory of movement, and the horizontal plane form an angle. The angle is indicated by α. The angle α is 30 °. The guiding angle of vibration is designated β. The ratio of β and α for the telescopic rod is expressed as β = 90 ° -α. The remaining parts are the same with preferred embodiment 4. Of course, the design of the rod limiting the path of motion in preferred embodiment 6 may be any one of preferred embodiments 1-5, forming different paths of motion.

Preferred Embodiment 7

In the embodiment shown in FIG. 11 of a vibration device with one shaft with the possibility of changing the path of movement, four groups of rod assemblies restricting the path of motion are mounted on the vibration box 1, and each group of rods limiting the path of motion is located symmetrically on both sides of the vibration duct 1. The rod assembly restricting the path of motion contains a rod 7, limiting the trajectory of movement, and a sliding sleeve 8.

The rod 7, limiting the trajectory of movement, located on one side of the vibration box 1, is located symmetrically with respect to the center of the longitudinal line on which the fixed axis of the vibration shaft 3 is located. The remaining parts are the same as shown in the preferred embodiment 6.

Preferred Embodiment 8

Shown in FIG. 12, the vibration device with one shaft with the possibility of changing the path of movement contains a vibration box 1, a lower support plate 2 and a vibration shaft 3. The vibration shaft 3 is mounted on the vibration box 1. The vibration springs 19 and the support brackets 4 integrated by the vibration springs 19 are installed respectively between four squares located between the vibration box 1 and the lower base plate 2.

The rod assembly restricting the path of movement comprises an arcuate guide groove 41 made in the support bracket 4, an arcuate slide rail 42 mounted in an arcuate guide groove 41, a rod 7 limiting the path of motion connecting to the arcuate slide rail 42, and a second end limiting the trajectory of motion, connecting with the vibration box 1 using the support shaft 43.

Each of the constructions of the trajectory changing mechanism is described below.

The support shaft 43 is fixed in the support socket 44 located on the vibration box 1. The rod 7, limiting the path of movement, is inclined between the vibration box 1 and the lower base plate 2. The upper end of the rod, limiting the path of movement, is pivotally mounted vertically to the support shaft 43 The lower end of the rod 7, limiting the trajectory of the movement, pivotally mounted on an arcuate rail 42 of the slide. The rod 7, limiting the trajectory of movement, is installed vertically to a fixed axial output of the vibration shaft 3.

The upper end of the vibration spring 19 is pivotally mounted vertically to the support shaft 43. The lower end of the vibration spring 19 is fixed in the arcuate slide rail 42 behind the spring seat 45. The rod 7 restricting the path of movement and the vibration spring 19 are arranged vertically.

The arcuate guide groove 41 is mounted on the support bracket 4. The arcuate slide rail 42 is mounted in the arcuate guide groove 41, and the arcuate slide rail 42 is fixed by the lock nut 46.

The length of the rod 7, limiting the trajectory of movement, is not adjustable. The slip interval m of the rod 7, restricting the trajectory of movement, is expressed as m = 0. The path of materials in the vibration box 1 is a straight line.

Preferred Embodiment 9

Shown in FIG. 9 and 13, the vibration device with one shaft with the possibility of changing the path of movement contains a vibration box 1, a lower support plate 2 and a vibration shaft 3. The belt pulley 53 is mounted as a coupling on the vibration shaft 3. The vibration shaft 3 is fixed to the vibration box 1 with bearings 54 bearings. Vibration springs 19 are installed between four angles located between the vibration box 1 and the lower base plate 2. The vibration shaft 3 is rotated by the electric motor 21 using the drive belt 22. The vibration shaft 3 is an eccentric shaft.

The rod assembly, limiting the path of movement and located obliquely, is installed between the vibration box 1 and the lower base plate 2. The rod assembly, limiting the path of movement, contains arched regulators located symmetrically on both sides of the vibration box 1, the rod 7, restricting the path of movement, the upper connecting a rod 52 and a lower connecting rod 51. Two arcuate regulators, two rods 7, limiting the path of movement, two upper connecting rods 52 and d a lower connecting rod 51 installed on each side of a shaft arrangement, which limits the motion path. The hinged quadrangle consists of rods 7, limiting the path of movement, the upper connecting rod 52 and the lower connecting rod 51. The arcuate regulator contains a support bracket 4. An arcuate hole 5 with a groove is arranged in the support bracket 4. The support bracket 4 is mounted on the lower base plate 2. Upper the ends of the two rods 7, limiting the trajectory of motion, both are pivotally mounted on the upper connecting rod 52, and the two upper mounting hinges are located on the vibration box 1. Two lower ca two rods 7, restricting movement trajectory, both articulated on the lower connecting rod 51, and two lower pivot mounting are respectively located in the two openings 5 of arcuate slots.

In FIG. 13 direction A is the direction of transportation of materials; direction B is the direction of the sliding linear motion of the rod 7, limiting the path of movement, i.e. the direction of the interval m can be adjusted; direction C is the direction of swing along the arc, i.e. the direction of the interval L can be adjusted.

The length of the rod 7 limiting the path of movement can be adjusted, and the mechanism of the rod limiting the path of movement is shown in FIG. 9. The kinematic pair consists of a rod 7, limiting the trajectory of motion, and a sliding guide rod 32, which can slide elastically. The sliding guide rod 32 is mounted in an external adjustable threaded rod 34. The sliding interval m can be adjusted by moving the thread forward and backward. As shown in FIG. 15, when m = L, the motion path is a circular motion path. As shown in FIG. 16, when m ≠ L, the path of motion is the path of elliptical motion. The coordinates of the rod 7, restricting the path of movement, are set using the sliding sleeve 8 to slide, so that the length of the rod 7, limiting the path of movement, is not fixed. When installing the rod 7, limiting the path of movement, in the factory, you can any requirements on the length of the rod 7, limiting the path of movement are easily satisfied. The internal adjustable threaded rod 37 is connected to the lower thread of the external adjustable threaded rod 34. The total length of the telescopic rod 31 can be adjusted by screwing and unscrewing to obtain the best installation and adjustment position. Before adjusting the total length of the telescopic rod 31, the upper lock nut 33 and the lower lock nut 36 must be released. After adjusting the total length of the telescopic rod, the upper lock nut 33 and the lower lock nut 36 are tightened. Pillow 35 silencing shock performs the function of silencing the sound of the shock.

One skilled in the art should understand that the embodiment of the present invention shown in the drawings and described above is only a non-limiting example.

It should be very clear that the objectives of the present invention are fully and successfully completed. Embodiments of the invention are shown and described to illustrate the functional and constructive principles of the present invention and are subject to change without departing from such principles. Therefore, the present invention includes all modifications encompassed by the spirit and scope of the appended claims.

Claims (13)

1. A vibration device for screening and feeding material, made with one shaft and with the possibility of changing the trajectory of movement and containing:
vibration box
lower base plate
vibration spring
vibration shaft;
wherein the vibration shaft is mounted on the vibration box, and the vibration spring is installed between the vibration box and the lower base plate; moreover, on two sides of the vibration box there are many groups of rod assemblies that limit the trajectory and are located obliquely; in this case, each group of rod nodes limiting the path of movement contains two rod nodes limiting the path of movement, which are located symmetrically on both sides of the vibration box, both ends of each rod node limiting the path of movement, pivotally attached to the vibration box and the lower base plate. 2. The device according to claim 1, in which when the number of groups of rod nodes limiting the path of movement is an odd number, in the rod nodes limiting the path of movement located on one side of the vibration box, the upper end of the hinge position of the rod node restricting the path of movement, in the middle position, it is installed on the longitudinal line, where the fixed axis of the vibration shaft is located; and other rod nodes limiting the trajectory of movement are located symmetrically on the longitudinal line, where the fixed axis of the vibration shaft is located. 3. The device according to claim 1, in which when the number of pivot nodes of the group limiting the path of movement is an even number, the pivot nodes limiting the path of movement and located on one side of the vibration box are located symmetrically with respect to the center of the longitudinal line, where the fixed axis of the vibration shaft. 4. The device according to claim 1, in which between the rod node, restricting the path of movement, and the horizontal plane in which the vibration box is installed, an acute angle is formed, the value of which is in the range from 30 ° to 60 °. 5. The device according to any one of paragraphs. 1-4, in which the rod node, limiting the path of movement, contains an arcuate regulator and a rod, limiting the path of movement; moreover, the arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; the first end of the rod, limiting the trajectory of motion, pivotally fixed in the hole of the arcuate groove; and the second end of the rod, limiting the trajectory of motion, is pivotally mounted on the vibration box. 6. The device according to any one of paragraphs. 1-4, in which the rod node, limiting the path of movement, contains an arcuate regulator and a rod, limiting the path of movement; an arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; the rod limiting the path of movement, contains an upper rod limiting the path of movement, and a lower rod limiting the path of movement; the threads are made on the outer peripheral surfaces of the upper rod restricting the motion path and the lower rod limiting the motion path, and the thread of the upper rod limiting the motion path and the thread of the lower rod limiting the motion path have the opposite direction; a threaded sleeve is installed in the connection of the upper rod, limiting the path of movement, and the lower rod, limiting the path of movement; the first end of the upper rod, limiting the trajectory of motion, pivotally mounted on a vibration box; the second end of the upper rod, limiting the path of movement, is placed in a threaded sleeve; the first end of the lower rod limiting the path of movement is pivotally fixed in the hole of the arcuate groove, and the second end of the lower rod limiting the path of movement is placed in the threaded sleeve. 7. The device according to any one of paragraphs. 1-4, in which the rod node, limiting the path of movement, contains an arcuate regulator and a rod, limiting the path of movement; an arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; the rod limiting the trajectory of movement contains a polished rod; sliding sleeve mounted on a polished rod; the sliding sleeve is pivotally mounted on the vibration box; and a polished rod is pivotally fixed in arched openings with a groove. 8. The device according to any one of paragraphs. 1-4, in which the rod node, limiting the path of movement, contains an arcuate regulator and a rod, limiting the path of movement; an arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; the rod limiting the trajectory of movement contains a polished rod; a screw spindle section is mounted at a first end of a polished rod, and a threaded rod section is mounted at a second end of a polished rod; the sliding sleeve is mounted on a polished rod; the diameter of the polished rod section is larger than the diameter of the screw spindle section; the length of the polished rod section is less than the length of the sliding sleeve; a combination of a lock nut and a lock nut is mounted on a section of a screw spindle mounted on a first end of a polished rod, and another combination of a lock nut and a lock nut is installed on a section of a screw spindle mounted on a second end of a polished rod; a spring with a shock silencer is respectively mounted as a clutch on a section of the shaft restricting the path of movement located between the sliding clutch and the lock nuts installed on both ends of the sliding clutch; the sliding sleeve is pivotally mounted on the vibrating box, and the screw spindle section is pivotally mounted in the arcuate holes with a groove. 9. The device according to any one of paragraphs. 1-4, in which the rod node, limiting the path of movement, contains an arcuate regulator and a rod, limiting the path of movement; an arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; a sliding sleeve is mounted on a rod restricting the path of movement; a sliding cavity is formed inside the sliding sleeve; the first end with the opening of the sliding cavity is connected to an adjustable threaded sleeve, the coordinates of which are set using the thread, and the second end to the hole of the sliding cavity is connected to the adjustable threaded rod, the coordinates of which are set using the thread; a guide channel connecting to the sliding cavity is installed inside an adjustable threaded sleeve; the rod limiting the trajectory of movement passes through the guide channel into the sliding cavity; the upper locknut is installed as a sleeve outside an adjustable threaded sleeve; the lower locknut is installed as a sleeve outside an adjustable threaded rod; a shock-suppressing airbag cushion matched to a rod restricting the trajectory of motion is mounted in the sliding cavity; the upper end of the rod, limiting the trajectory of motion, pivotally mounted on a vibration support; and the lower end of the adjustable threaded rod is pivotally mounted on the lower base plate. 10. The device according to any one of paragraphs. 1-4, in which the rod node, restricting the path of movement, and a vibration spring are installed on one lower base plate; the rod node, limiting the trajectory of movement, contains an arcuate guide groove mounted on the lower base plate; an arcuate slide rail is installed in an arcuate guide groove; an arcuate slide rail connected to the first end of the rod, limiting the path of movement; the second end of the rod, limiting the trajectory of motion, is connected to the vibration box supporting shaft; the first end of the vibration spring is connected to the vibration box by a support shaft; the second end of the vibration spring is fixed to the spring support; and the spring support is mounted on an arcuate slide rail. 11. The device according to p. 10, in which the vibration spring is vertical to the rod, limiting the path of movement. 12. The device according to any one of paragraphs. 1-4, in which the rod node, restricting the path of movement, contains two arcuate regulators, two rods, limiting the path of movement, the upper connecting rod and the lower connecting rod; an arcuate regulator is mounted on the lower base plate; arcuate holes with a groove made on an arcuate regulator; both upper ends of the two rods limiting the path of movement are pivotally mounted on the upper connecting rod, and two hinge fasteners are located on the vibration box; both lower ends of the two rods limiting the path of movement are connected to the lower connecting rod, and two hinge fasteners are respectively located in two arcuate openings with grooves; and a rod restricting the trajectory of motion is connected to the design of the sliding interval. 13. The device according to p. 12, in which the design of the interval of sliding contains a sliding rod; the sliding cavity is located in the sliding rod; the first end of the rod, limiting the trajectory of movement, passes into the sliding cavity; a rubber cushion for silencing the impact sound is installed in the sliding cavity; an external adjustable threaded rod is installed outside the sliding rod; the sliding rod is fastened with an external adjustable threaded rod with the upper lock nut; an internal adjustable threaded rod is mounted at a second end of the external adjustable threaded rod; the hinged end of the internal adjustable threaded rod is pivotally mounted on the upper connecting rod, which is pivotally fixed in the hole of the arcuate groove; and the internal adjustable threaded rod and the external adjustable threaded rod are fixed with the lower lock nut.

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