RU2064348C1 - Vibrating screen - Google Patents

Abstract

FIELD: purifying drilling fluid. SUBSTANCE: vibrating screen has a load-carrying screening surface at least two sides of which are fixed and a vibration drive that is arranged along the side fixing and made up as at least two plates spaced from each other in the direction of the sides fixed. EFFECT: improved design. 10 cl, 1 dwg

Description

 The invention relates to means for separating mixtures into solid and liquid phases and solid phase into fractions using moving screening surfaces.

 It can be used to clean drilling fluids from cuttings, for sorting grains, flour and so on.

 Known vibrating screens containing a screening surface in the form of a grid, mounted in a frame on fixed supports, and a frame vibration drive, for example, according to US patent N 3101314, class. 209,319.

 The disadvantage of this sieve is the tight connection of the mesh with the frame. This limits the amplitude and frequency of the grid vibrations to the vibrations of the frame itself, and, consequently, to the strength properties of this frame and its mass, which requires considerable energy to bring into vibrational motion. As a result, the screening ability of the vibrating screen is limited.

 This disadvantage is somewhat reduced in the separation device according to the patent of Germany N 2950615, class. B 07 B 1/10. In this device, the grid is placed on supports having their own vibration drive, the mass of which may be less than that of the frames in which the grid is mounted in known vibrating screens.

 However, in this design, the amplitude of the mesh oscillations is also limited, due to the size ratio of the used support drive levers. The frequency is limited by the wear resistance of the articulated mechanism of the drive of the supports, as well as by the cost of energy, a significant part of which will be lost on friction in the joints.

 The mentioned drawbacks are partially eliminated in the "Sieve for the classification of bulk materials" according to AS No. 645714, cl. B 07 B 1/12. In this sieve, due to the use of springs as a support, the mesh has the ability to obtain additional vibrations, for example, arising from the discharge of sieving material onto it. However, the same springs limit the amplitude and frequency of such vibrations. This is due to the fact that the springs must be stiff enough, since they also provide the necessary mesh tension.

 Most of the shortcomings of the mentioned devices are eliminated in the "String sieve" by a.s. N 1371718, CL B 07 B 1/04. This screen uses a screening surface that carries the load without any additional support underneath. This creates the possibility of various oscillations of the grid, both in amplitude and in frequency, including regardless of the frame in which it is mounted.

 This device is taken as a prototype.

 However, it has a significant drawback, which consists in the following. The amplitude and frequency of additional oscillations of the screening surface is determined by the movement of the load. But the load is placed in one line along the fastening of the sides of the screening surface. For this reason, the maximum amplitude of the surface will be near the load itself, on both sides of it. Closer to the side mounts, this amplitude drops. As a result, all parts of the surface operate with different amplitudes. This dramatically reduces the efficiency of the vibrating screen both in terms of productivity and the quality of sorting the material. The formation of stagnant zones with subsequent clogging is also possible on the surface.

 The aim of the invention is to increase the productivity and quality of sorting in a vibrating screen with a screening surface that carries a load placed on it along the fastening sides of this surface.

 The essence of the invention lies in the fact that the load consists of at least two plates spaced from each other in the direction of the reinforced sides.

 In addition, in embodiments, the cargo includes fastening elements of the plates together; plates are placed on the screening surface with the ability to control the distance between them; the part of the screening surface located between the plates of the load, and part of it between the plates and the fastenings of the sides have a different structure; parts of the screening surface located on opposite sides of the plate are interconnected through this plate; the screening surface between the fastening of its side by a plate is formed by rods connecting the rest of it with frame points spaced in height; the plates are made in the form of partitions separating the screening surface from above; the load includes at least one screen at the edge of the screening surface; the vibro drive is connected to the load; the frequency of the vibrator corresponds to the resonant vibrations of the load with a screening surface.

 These features provide the same frequency and amplitude of oscillations of most of the screening surface and the ability to control these parameters. The amplitude and frequency can be resonant and, therefore, very significant. At the same time, the productivity and quality of work of the vibrating screen sharply increase.

 The drawing shows an embodiment of the claimed vibrating screen. It contains a screening surface 1 in the form of a set of strings stretched in the frame 2. The strings pass into the holes of the plates 3 and 4. The plates are interconnected by screws 5 and 6, together with which they form a load 7 on the screening surface. In this case, the load consists mainly of two parts spaced from each other in the direction of fastening the strings. An electromagnetic vibrodrive 8 is installed on the frame, which interacts with the load, for example, through screw 5. It is possible to use a vibrodrive that interacts with the frame, including unbalanced and any other.

 In an embodiment, the fastening of the screening surface can be carried out by double rods 9 passing between the plate and the wall of the frame to the points of this wall, spaced in height (view near the left wall of the frame). As rods can be used springs, strings, including extensions of strings forming a screening surface 1 and so on.

 Plates 3 and 4 can be made in the form of partitions 10 dividing the screening surface from above (shown on plate 4).

 At the edge of the grid, from the side of the vibrodrive 8, a screen 11 (a fragment is shown) can be placed, which is screwed to the partitions 10 and is thus included in the cargo 7.

 The vibrodrive 8 can be selected with a frequency corresponding to the resonant vibrations of the load along with the screening surface.

 Frame 2 can be mounted on shock absorbers 12.

 Vibrating screen works as follows.

 Frame 2 is driven into oscillatory motion on shock absorbers 12, for example, by an unbalanced electric drive (not shown in the drawing). Oscillations through the strings of the screening surface 1, located between the plates 3, 4 and the walls of the frame 2, are transmitted to the load 7, which swinging can give this surface vibrations that are larger in amplitude than the frame itself. Due to this, it is possible to increase the performance of the vibrating screen while reducing the energy flow supplied to the frame.

 Due to the fact that the main part of the load is made of two spaced plates, the screening surface between them acquires vibrations that are identical at all points between the plates. This dramatically increases its productivity compared to the prototype, as well as the quality of sorting. The likelihood of clogging is reduced.

 When using a vibrodrive 8, which interacts directly with the load 7, this vibrodrive will be installed on the frame, which remains generally stationary. In this case, the mass driven into oscillatory motion is limited to the actual load 7 with a screening surface. In this case, the required energy flow is further reduced.

 By spreading the plates 3 and 4 with each other using screws 5 and 6 (for example, with left and right threads at the ends), the screening surface can be increased. Bringing them together you can get more rigidity of this surface. By adjusting the distance in this way, it is possible to find its optimal value in terms of the performance of the vibrating screen. When the distance between the plates changes, the rigidity of the oscillating system also changes, due to which the amplitude and frequency of oscillations, which also affect the performance, can be controlled.

 If double rods 9 are used, then the vibrations of the load, and, accordingly, the screening surface will have a predominantly fixed orientation, perpendicular to the plane in which the intersecting rods 9 are located. This is also a reserve for increasing the performance of the vibrating screen due to the replacement of circular vibrations by linear and close ones.

 With this design, in particular, a different structure of the screening surface was used. Part of it, between plates 3 and 4, is used for separation itself. Part of it, between the plates and the walls of the frame, for the direction of oscillatory movements. Moreover, the screening surface itself may not necessarily be a string, but any other, for example, in the form of a grid. This separation of the function of the parts of the surface also allows to optimize its work. This design is facilitated by the presence of plates 3 and 4. Parts of the screening surface can be made separately, and interconnected via plates, which increases, moreover, the adaptability of the vibrating screen (shown on plate 3).

 The load can play the role of simultaneously guiding the material to be separated if the plates are made in the form of partitions 10, i.e. greater height. This prevents the ejection of the separated material from the screening surface. The use of the screen 11 at the edge of the screening surface also contributes to this. In addition, the screen connected to the partitions 10, gives rigidity to the structure of the load, which is important given its work in constant vibration mode. The screen provides additional fixation relative to the position of the plates 3 and 4 after adjusting the distance between them. The screen can also be the main part of the load interacting with the vibrodrive 8, instead of the screw 5, or to strengthen this interaction.

 If the vibrating actuator 8 provides resonant vibrations of the load 7 with a screening surface, then the amplitude of the oscillations will be maximum and the productivity of the vibrating screen and the quality of sorting will sharply increase.

Claims (10)

 1. Vibrating screen containing a screening surface, reinforced by at least two sides in the frame and carrying a load placed on it along the side fastening, and a vibrodrive, characterized in that the load consists of at least two plates spaced from each other in the direction of the reinforced parties.  2. Vibrating screen according to claim 1, characterized in that the load includes fastening elements of the plates together.  3. Vibrosieve according to paragraphs. 1 and 2, characterized in that the plates are placed on a screening surface with the ability to control the distance between them.  4. Vibrosieve according to paragraphs. 1-3, characterized in that the part of the screening surface located between the plates and the mountings of the sides, has a different structure.  5. Vibrating screen according to claim 4, characterized in that the parts of the screening surface located on opposite sides of the plate are interconnected through this plate.  6. Vibrosieve according to paragraphs. 4 and 5, characterized in that the screening surface between the fastening of its side and the plate is formed by rods connecting its rest with points of the frame spaced in height.  7. Vibrosieve according to paragraphs. 1-6, characterized in that the plates are made in the form of partitions, dividing the screening surface from above.  8. Vibrosieve according to paragraphs. 1-7, characterized in that the load includes at least one screen at the edge of the screening surface.  9. Vibrosieve according to claims 1-8, characterized in that the vibrator is connected to the load.  10. Vibrosieve according to paragraphs. 1-9, characterized in that the vibrator has a frequency of resonant vibrations of the load with a screening surface.