RU2189863C2 - Device for gravity inertial dynamic concentration - Google Patents

Abstract

FIELD: separation of solid materials by means of liquid at technological treatment of mineral raw material and study of such materials. SUBSTANCE: proposed device includes bed frame, starting material and liquid loading mechanism, inclined working surface, barriers located over edges of working surface which are provided with holes for escape of fractions of starting material and reciprocating mechanism. Device has metal framework with limiting hole on one side where spring- loaded rod transversal motion is located; this rod is connected with drive of reciprocating mechanism; device is also provided with slider fitted with guide secured at angle relative to transversal direction of working surface and fitted with tightening spring. Secured on bed frame near lower unloading part of working surface are limiting barriers of reciprocating motion and limiting barrier connected with spring-loaded longitudinal motion rod is located at upper part of working surface; working surface is rigidly secured on metal framework. Barriers located over edges of working surface are so mounted that they narrowing chutes. EFFECT: increased productivity; simplified construction. 2 cl, 1 dwg

Description

 This proposal relates to the field of separation of solid materials using liquids and can be used in technological research and mineral processing.

 A device for gravitational inertial-dynamic enrichment, including a bed, a mechanism for loading the source material and liquid, an inclined working surface with an upper loading part and a lower unloading part, high obstacles located at the edges of the working surface, with holes in them for outputting fractions of the source material, a mechanism for reciprocating motion, spring traction connecting the working surface with this mechanism (V. Apolitsky, RF patent 2085295, 1995).

 The closest technical solution and essence to this proposal is a device for gravitational inertial-dynamic enrichment, including a bed, a mechanism for loading source material and liquid, an inclined working surface with an upper loading part and a lower unloading part, high obstacles located at the edges of the working surface, with holes in them for outputting fractions of the source material, a mechanism for reciprocating motion, spring traction connecting the working surface with this mechanism (Apolitsky VN, RF Patent 2092244, 1995).

 The disadvantages of technical solutions (analogue and prototype) is the low productivity and complexity of the devices.

 The purpose of the proposal is to increase the productivity of the installation, simplifying the design.

 This goal is achieved due to the fact that the device for inertial-dynamic enrichment, including a bed, a mechanism for loading the source material and liquid, an inclined working surface, obstacles located at the edges of the working surface, with holes in them for outputting fractions of the source material, the mechanism is reciprocating translational movement, equipped with a metal frame, on one side of which a restrictive hole is made and a spring traction of longitudinal movement is fixed, and on the other hand is located lateral spring traction associated with the drive of the reciprocating movement mechanism, and a slider with a guide fixed at an angle to the transverse direction of the working surface and having a tightening spring, while restrictive barriers of the transverse reciprocating movement are fixed on the bed at the lower unloading part of the working surface and at the top of the working surface there is a restrictive barrier in the restrictive opening connected to the spring rod of the longitudinal izheniya, wherein the working surface is fixedly mounted on a metal frame.

 Obstacles located along the edges of the working surface are installed with the formation of tapering gutters.

 The essence of the proposed device is as follows.

 A device for gravitational inertial-dynamic enrichment consists of a movable inclined working surface with high obstacles and holes in them for outputting fractions (for example, an inclined tapering chute suspended on cables in space and having a transverse partition in its lower narrow end), a pulp feeding mechanism in the upper loading part of the working surface, the mechanism of the transverse reciprocating movement with a spring rod connected to the lower part of the working surface, as well as the limiter ( For example, holes) and restrictive barriers (e.g., pin which is located in the hole), which allow to limit the movement of the upper loading portion of the working surface, and limiter - barriers which limited via transverse reciprocating movement of the lower portion of the discharge working surface. In order to create a longitudinal inertial movement of the heavy fraction relative to the working surface down, there is a spring rod, which attracts the upper edge of the restrictive hole to the restrictive barrier pin, and a guide of limited length, located at an angle to the transverse direction of the working surface, with a slider which, interacting with the guide of limited length during the transverse reciprocating movement of the working surface, leads to movement in the space of the working surface in partite direction towards its upper discharge part until the termination of this interaction.

 When the transverse reciprocating mechanism is switched on, its drive through the spring traction carries out the transverse reciprocating movement of the lower part of the working surface, which is interrupted by impacts on restrictive barriers, and at the same time, due to the interaction of the slider with the guide, the working surface is shifted in the longitudinal direction towards the upper loading parts, while the upper edge of the restriction hole is removed from the restriction pin, the spring rod is stretched longitudinal movement of the working surface. Further, the interaction of the slider due to the limited length of the guide stops, the working surface of the tensioned spring rod moves in the longitudinal direction downward towards the unloading part until the limiter of the longitudinal movement hits the restrictive pin. The movement of the working surface down abruptly stops. Thus, the movement of the working surface is created with its interruption both in the transverse and longitudinal directions, as necessary for the implementation of the gravitational inertial-dynamic method of enrichment.

 In order to increase the productivity of the installation in the lower discharge part, the shape of the working surface with high obstacles at its edges forms several gutters, while the number of holes for outputting fractions of the source material increases. This allows you to speed up the unloading of light and heavy fractions, to increase the productivity of the installation.

 An example implementation of the proposed device.

A flat work surface 1 is made (see drawing) with high obstacles (walls) 2 located along its edges (stainless steel), which form two discharge tapering channels 3 and 4, blocked by obstacles (partitions 5 and 6). The length of the working surface 1 is 700 mm, and the width of the wide upper loading part of the working surface is 500 mm, the lower narrow discharge ends of the tapering grooves 3 and 4 (obstacles-barriers 5 and 6) are 40 mm. Near the partitions 5 and 6 in the upper parts of the side walls of the troughs 3 and 4, adjustable holes 7 are made for outputting the light fraction, and in the lower part of the partitions 5 and 6 at the working surface 1 are made adjustable holes with a gate 8 for outputting the heavy fraction. The working surface 1 is rigidly mounted in a metal frame 9, which has a restrictive hole 10 and a spring link 11 mounted longitudinally adjacent to it. On the other side of the frame 9 there is a spring rod 12 and a slider (roller) 13. The frame 9 with the working surface 1 is suspended in space at an angle to the horizon of 7 ^o using cables fixed to the frame (not shown) so that the wide loading part of the working surface 1 was above the discharge part. On the bed, restrictive barriers 14 of the transverse reciprocating movement are fixed at the lower unloading part of the working surface, as well as a limiter bar (pin) 15, which should be in the restrictive hole 10, and the second end of the spring rod 11 is connected to the pin 15 so that the upper edge the holes 10 were pulled by a spring rod 11 to the pin 15. In addition, on the bed near the slider 13, a guide 16 is fixed (with a lifting spring 17), the length of the guide is 16-50 mm, and it is fixed at an angle to the transverse direction leniyu work surface 1, and near the spring rods 12 the transverse motion placed mechanism transverse reciprocating movement (speed 100 osc / min, the amplitude of 100 mm) (not shown) with a drive 18 which is attached to the second end of the spring rods 12 the transverse motion. Near the upper loading part of the working surface 1 is a mechanism for loading the source material with a liquid (not shown).

 To carry out gravitational inertial-dynamic enrichment of aluminosilicate ore, a transverse reciprocating mechanism is switched on and a source material mixed with water is supplied. During the transverse reciprocating movement of the drive 18, the frame 9, the working surface 1 and the slider 13 make transverse reciprocating movements, while the slider 13 periodically interacts with the guide 16, during the time the slider 13 rests against the guide 16, moves the frame 9, and together with it and the working surface 1 in the longitudinal direction. Having reached the end of the guide 16, the slider 13 comes out of contact with the guide 16, while the spring rod 11 is tensioned. The spring rod 11, upon exiting the interaction of the slider 13 with the guide 16, accelerates the working surface 1 in the longitudinal direction toward the lower edge of the unloading part of the working surface until the upper edge of the restriction opening 10 hits the restrictive barrier - pin 15. At such a stop the movement of the working surface 1, the heavy fraction located on this surface by inertia will periodically continue its downward movement. The working surface 1 after disengaging the slider 13 with the guide 16 will continue its movement in the transverse direction until the lower lateral edge of the frame 8 hits the barrier 14 of the transverse reciprocating movement, while the working surface abruptly ceases to move transverse direction. The drive 18 pulls the spring rod 12, and then with the return movement of the actuator 18, the spring rod 12 is compressed, and then stretched and resumes the movement of the working surface 1, but in the other direction. With this movement, the slider 13 passes freely from the back of the guide 16 having a spring 17, which allows the guide 16 to be suspended by the slider 13 (this short-term effect does not lead to the movement of the working surface). The transverse movement of the working surface 1 continues until another barrier 14 meets on its way, while the movement of the surface 1 abruptly stops. Further, the process of movement and its termination are periodically repeated, consistent with the reciprocating movement of the drive 18.

 Thus, the basic conditions for the implementation of gravitational inertial-dynamic enrichment are fulfilled - there is a transverse and longitudinal reciprocating movement of the working surface 1 with sharp negative accelerations at the moment of impact on obstacles 14 and 15. The pulp, running down the working surface under the influence of gravitational and dynamic forces, first stratified in height in the upper part, and then in the lower part of the working surface under the action of segregation, which is facilitated by the inertial movement of particles in moments of sharp movement of the working surface during impacts on obstacles. The light fraction of the source material is discharged through the holes 7 of the side walls of the lower parts of the tapering grooves 3 and 4, and the heavy fraction through the holes 8 located in the lower part of the partitions 5 and 6.

 As a result of the enrichment of aluminosilicate ore, the light fraction contained minerals with a specific gravity of less than 3 g / cm (quartz, feldspar, and other aluminosilicate minerals), while the heavy fraction contained cassiterite, tungsten, galena, and also particles of native metals.

 The presence of several narrowing grooves 3 and 4 in the proposed device will increase the number of loaded source material and thus increase the productivity of the installation.

 Thus, the proposed device simplifies the design of the device for the implementation of gravitational inertial-dynamic enrichment, at the same time it allows to reduce energy consumption through the use of a single reciprocating mechanism, as well as to increase productivity due to the special shape of the working surface (several grooves) and a large number of holes for output fractions compared to the prototype.

Claims (2)

 1. A device for inertial-dynamic enrichment, including a bed, a mechanism for loading the starting material and liquid, an inclined working surface, obstacles located at the edges of the working surface with holes in them for outputting fractions of the starting material, the mechanism of reciprocating movement, characterized in that it is equipped with a metal frame, on one side of which a restrictive hole is made and a spring traction of longitudinal movement is fixed, and on the other hand there is a spring traction target movement associated with the drive mechanism of the reciprocating movement, and a slider with a guide fixed at an angle to the transverse direction of the working surface and having a tightening spring, while on the bed at the lower discharge part of the working surface fixed restrictive barriers of the transverse reciprocating movement, and at the top of the working surface there is a restrictive barrier in the restrictive opening connected to the spring traction of longitudinal movement, while The tea surface is rigidly mounted on a metal frame.  2. The device according to 1, characterized in that the obstacles located at the edges of the working surface are installed with the formation of tapering gutters.