BR102013005032A2 - Mineral Separator - Google Patents

Abstract

Mineral Separator. The mineral separator is a steel frame machine designed to support all its components, arranged in adjustable galleries, to separate various types of metallic and non-metallic minerals. It has bold design in both its performance and functionality. Positioned at a 50 to 20 degree tilt angle, made by a support composed of hydraulic devices, which allows the collection of the material to be classified, with an operating capacity of up to 100 tons per minute. All galleries are made up of tables whose belts float through the jet squirted by spray elements, which provide an intense and constant flow of water through the pipelines arranged as conductors, where all the mineral paths were designed. to be selected, sorted and finally harvested.

Description

MINERAL SEPARATOR

This patent relates to a separator designed to combine the functions of separating, collecting and storing minerals in compartments, thereby providing greater separation in a short time.

All the equipments that make up the separator are assembled in cascade form, processing all the material through gravity action, eliminating the need for pumping. All belt translation systems are on tables with pressure-injected water slides that clean the table surface and the bottom of the belt. Solid material is fed through the conventional conveyor belt or pumping, where the material is already mixed with water. The solid material to be classified is placed inside a pyramidal silo where it injects water under pressure, where it mixes the falling material, from that moment the selection process begins. The conveyance of the material in the conveyor belt is flattened and flattened on a horizontal table, moving to the descent stage on an inclined table with respect to the horizontal. The belt at this stage is shell-shaped upwards. It has devices that allow to make changes in the cross section of the moving belt, being able to toggle its curvature from concave to flat and from flat to convex, according to the need of material classification. Material separation occurs on both sides of the belt, has three compartments on each side, the material is classified according to its weight and particle size range, including tailings.

Materials not classified in this process will be directed to a second or third classification step to their full extent.

All belts have a transport speed adjusting device that allows the change of particle size ranges at the belt side exits. The mineral separator can be better understood by the following detailed description, in line with the attached figures, where.

FIGURES 1 to 24 represent the separation structure with its possible divisions, each type of material to be separated requires a type of division. FIGURE 25 represents the beginning of separation in top view. FIGURE 26 represents the side section of the table. FIGURE 27 represents the separation structure. FIGURE 28 represents the actuation of the cleaning system. FIGURE 29 represents the support roll. FIGURE 30 represents the force roll. FIGURE 31 represents the base of the roll stretching system. FIGURE 32 represents the cylinder of the gravitational sieve system in side view. FIGURE 33 represents another part of the same cylinder. FIGURE 34 represents the conical inlet. FIGURE 35 represents the system providing clean water. FIGURE 36 represents the channels. FIGURE 37 represents the belt cleaning system. FIGURE 38 represents the separation cone. FIGURE 39 represents the side view separation system. FIGURE 40 depicts the system in side view and belt rotation carrying the dried material. FIGURE 41 represents the transport of the material to its highest point and its fall. FIGURE 42 represents the system in another application for more complex materials. FIGURE 43 is the same as FIG. 42, but at another angle. FIGURE 44 is a top view of an application where the movement is not about belts but about a circular area. FIGURE 45 represents the same application as the previous figure, but in side view.

With reference to figure (1) one can observe the structure of separation of materials in size and weight, it can be mounted on the belt, or the belt will be shaped, or it will be fixed on a structure like a disk, in motion. circular with one or more inclines that will pass in a circular way, together with the material separation structure in one region the material will enter and in another will already be transported.

During the following figures all inclinations will be presented, in this structure there is also application of magnetism, and flexible materials, which will increase the force of gravitation for separation of materials. The inclinations will always vary according to the material to be separated, always working with gravitation, and some adjustments with magnetism. Magnetism may be situated in the flexible moving structure as explained, either alone or in parts, or even in parts of the table. The diamond is proportional to the highest point. The slope enters from the vertices (1) towards the center of the belt (3).

With reference to figure (2) the maximum inclination can be observed, it operates from 0 to 99 degrees, the material separation structure will be mounted on the belt (3).

With reference to figure (3) one can observe the maximum slope in another room.

With reference to figure (4) one can observe a division (2) f it is lower than the highest area (1).

With reference to figure (5) one can observe two divisions (2).

With reference to figure (6) one can observe four divisions (2).

With reference to figure (7) one can observe five divisions (2).

With reference to figure (8) one can observe six divisions (2).

With reference to figure (9) one can observe seven divisions (2).

With reference to figure (10) one can observe eight divisions (2).

With reference to figure (11) one can observe eleven divisions (2).

Referring to Figure 12, the quadrangular separating extrusion can be seen; the highest point (1), as stated above, will be mounted on the belt, which may have the shape of several diamonds or several squares.

With reference to figure (13) one can observe the highest point (1), with an inclined division and another flat place.

Referring to figure 14, it can be seen that the inclination has a slightly greater distance than the previous one.

With reference to figure (15) one can observe a division (2) and the highest point (1).

Referring to Figure 16, two divisions (2) can be seen, the highest point (1) and the belt (3).

Referring to figure (17) one can see three divisions (2), the highest point (1) and the belt (3).

Referring to figure 18, four divisions (2), the highest point (1) and the belt (3) can be seen.

Referring to figure (19) one can observe five divisions (2), the highest point (1) and the belt (3).

Referring to figure 20, seven divisions (2), the highest point (1) and the belt (3) can be seen.

With reference to figure (21) one can see eight divisions (2), the highest point (1) and the belt (3).

With reference to figure (22) one can observe eleven divisions (2), the highest point and the belt (3).

Referring to figure 23, one can observe the material separation structure mounted on diamonds.

Referring to figure 24, the square material separation structure can be seen.

Referring to figure (25), the vibration counterweight (11), vibration system (12), support roller (13), force roller (14), material inlet (15) can be seen. which will be top to bottom and will be spread over the belt (10). The application (16) of water under the belt (10), to facilitate its movement and the dirt does not accumulate between the table and the belt. Flexible part (19) between vibrating frame and fixed frame (29). The attachment (20) has the same function as the flexible blade (19), or thicker parts with the same strength will be mounted. Fixed structure (21) where the flexible parts (19) will be fixed. By tilting the lighter material (6) with less grain and the position of the belt height changes and placing liquid on the belt, the material will either be used in place (4) or thrown away. The removal system (4) of all heavier moving material, after which the belt (3) will pass clean and then one side will be clean and the other concentrated in continuous process.

Referring to figure 26, the table section can be seen. The separation structure (22), the flexible part (19), which can also be mounted on site (23). The application (16) of water below the belt (10), which facilitates its movement and prevents the accumulation of dirt between the table and the belt (10).

Referring to figure 27, one can see the separation structure 22, the center 24, which indicates that the two sides are equal, the central tube 25, which will be mounted on two sides or on the center. Tube (26), where the water release system will be mounted on the rubber. Non-vibrating structure (27), which serves as a fixture. Non-vibrating structure (28) where the vibratory system (12) will be fixed. The application (16) of water below the belt (10), which facilitates its movement and prevents the accumulation of dirt between the table and the belt (10).

Complete system structure (29), it does not vibrate and hold the vibratory system (12). The fixture (30) is mounted on the frame (20).

Referring to figure 28, one can see the force roller 14, the table 9, the expansion area of the system 41, the water application below the belt 10 which facilitates its operation. movement and prevents dirt from accumulating between the table (9) and the belt (10). Flexible tube (40) which joins the tube (26) and (39). The water inlet pipe (39) into the cleaning system located in the central pipe (25). Water outlet (35) in cleaning system (36). The direction of the water jet (37) and the non-vibrating structure (38) where the cleaning system will be mounted.

Referring to figure 29, one can see the support roller 13, the bearing 44 between the fixed shaft and the rotary cylinder. The fastener (43) is fixed between the axle and the tensioner system. The tube (45) where the bearing will be fixed is larger so that water does not enter the bearings and has a spiral so that dirt always goes out. The protection system (46) is mounted on the shaft to prevent water or dirt from entering the bearings. Fixed shaft (47), frame (48) securing between tube (45) and cylindrical roller (49). The cylindrical roller is thicker in the center (50) so that the belt does not escape from the roller.

With reference to figure (30) one can see the force roller (14), the rubberized cylinder (51) with conical shape, the reason is to leave the rubber in position. The pulley fezao © no íossij pr.rc; apply the rotating tools to the force cylinder (53). Fixing structure (48) between the tube (45) and the cylindrical roller (49).

Referring to figure 31, one can see the base of the roller tensioning system 61, the frame 62 mounted on the system 61, and the attachment of the vibrating arms. Area (66) that slides the part (43) into position. The plate (67) which surrounds the screw (63) and is secured with nuts in the support position.

It will pick up the vibration of the flexible damper (68), which will be secured around the shaft (64) and bolt (63), and secured at locations (65) and (67), tightened with the nuts that will be around the screw (63). The damper (69) which cushions the force toward the damper (68). The plate 70 has the same function as the 67. The nut (71) will be screwed onto the screw (63) to press the damper under regulation. The bearing (72) is mounted on the vibratory system bearing and fixed to the shaft (64). The bearing (73) is mounted on the bearing that secures the rotary vibratory system shaft (74). The fixing (76) pressure.

Referring to figure 32, one can observe the cylinder 80 of the gravitational sieve system, which may be super thin in equilibrium with the gravitational force. On the flank a conical tube (81) will be mounted in the passage where the tube will be fixed, in this curve the central tube will be fixed. The cone (82) mounted on the gravitational sieve system. Upright pipe (83) from the bottom of the water enters the system and passes through the location (82) towards the gravitational sieve system. Cleaning tube (84), tube (85) where water enters to balance water level (79). Water Direction (86).

When the system is turned off (87) water will be released at location (84) or (86) and dirt accumulated below the gravitational sieve system will be released along with the water. Water pressure decreases (88), so the heaviest dirt that water accumulates on the sides of the cylinder (80). The lighter material floats in circulation in the water (89) of the cylinder (80). The gravitational sieve (90) which will be mounted in a system that fully divides into the cylinder (80) so that only sieve size particles will pass into the location (81). The tubes (91) extend the hose into position. End part (92) of the structure that opens or closes the sieve (90), it may pull and open a passageway towards (82) if necessary. Flexible fixing (93) rubber type. The rail (94) where the pipes (94) will be positioned. The zigzag clamping form increases the sieve area and proportionally reduces the velocity of the incoming water from (88) to the location (25) so that the gravitational forces are greater than the suction of the horizontal tubes, thus the grains more Heavy loads accumulate in the cylinder area below the sieve and are automatically removed with the lightest dirt as explained when the system is turned off. This will achieve a free-flowing water system in constant separator production without covering areas with less fluid circulation.

With reference to figure 33 one can observe the same location already explained in figure 32, but here there is another position.

Referring to figure 34 one can observe the conical inlet 95 which can vary from 2 to 20mm in the outlet location 96, the entry will be numbered or have different colors to classify which one will be used. By the operation of the gravitational screen the outlet 96 is not clogged and in each part of the machine different cones will be mounted. The fluid layer 98 at the outlet will be uniform.

Referring to figure 35, the upper water system is provided, which provides clean water for the collection of materials. The blades (97), the register (®G), the fcsk © ζβΖ). Co-ordinating machines for use, use or return to the machine. Rubber (101), gravitational fins (102), registration (103), structure (104).

Referring to figure 36, one can see the force roller 14, the support roller 13, the channel 32, the non-vibrating frame 27, the inclination changes 33 in the construction. of the table sides throughout the installation. The rubber (101), the belt (105), and the gravitational channel (106) which returns the unpumped material to the location of materials not yet finished as finished products.

With reference to figure (37) the belt cleaning system can be observed, this equipment has the objective of removing all the noble material.

Through the valve, raw material is diverted to its storage location.

Other materials that have not yet been separated return to other valves for reuse. The water inlet tube (39), the water jet (37), the blades (97), the cleaning register (107) which cleans the tube (39). The connecting tube (108), the ready material channels (109). On the sides 110 pass the heavier and thicker materials, in the middle 111 pass the heavier and thinner materials. The falling material will either go to channel (109) or channel (32).

With reference to figure 38 one can observe the direction of the material 114 in the cone where there is an opening 115, so at the highest position there is an equilibrium of the pressure of the vertical pumping of the material which is losing speed due to gravitation. In a larger space the material has less speed to pass. At position (116) the material is fully calibrated with velocity and pressure and gravitation, so this material begins to turn (117) around the falling cone. At the end of the cone (120) begins another cone in the opposite position, where a sieve will be mounted that separates the larger grains from the smaller ones, this material falls at the end of this cone, where will be mounted another c © nju q βοκακϊϋ? © the rastoís !) çus ss: 5 s! a psr.sirs, this is a tenuous point at the material entry point (15).

Referring to figure 39 one can observe the system in side view, the direction of the material in the tube 138, all components have already been explained in previous figures of the patent.

Referring to figure 40, one can observe the system in side view, the rotation of the belt carrying the dried material 139, the falling of the dried material 140. Around the conical structure are several water jets that gather the falling material into a soup. This material will pass through the channel 142 where it will be mixed with liquid. At the end (143) of the passage of such material, the material separation process begins (15), where the material will be conveyed by the separator belt and the material will be separated.

Referring to figure 41 it can be seen that the material being conveyed to the highest point of the sieve 147 will fall 148 and will accelerate in proportion to gravitation toward the location 149. In place (149) will be mounted iron bars, some higher and some lower and they will have a slope. The iron bars “brake” the material in the fall, so the more fragile material '' pops '' over the bars and enters the far sides of the bars and the material goes back to the sieve, whatever passes the sieve enters another time in the process. The solid stones that are transported and fall in the same place do not burst, but rather slide over the sloping bars.

Referring to figure 42, the system in side and top view can be seen in more detail in another application for more complex materials, so it has been divided into galleries. The system will be mounted horizontally.

Referring to figure 43, one can observe the clean water inlet 152, safety valve 153 which interrupts the flow of water at the time of machine maintenance. Sieve (USAGE), c-orn © metastol (1SS) outlet when the relief valve is not closed. Dredge inlet (15 ©), second dredger inlet (157).

Referring to Fig. 44, another application for the system can be seen in top view where it will not be by movement of the belts, but over a circular area with one or more inclines that will pass circularly, together with the separation structure. of the materials in one region the material will enter and another will already be transported The material after passing through the cone (158) will reach the channel (163) which has an opening (164) which divides the material for the circular table (161). The separation area (165) will be placed on the circular table, and on that area will be placed the fixed cleaning system.

Rotary is just the table and its structure. Material fall (166), channel material outlet, fixed channel for tailings (like 32). The areas will be fixed in a circular structure and will circle in the direction (169) or in the opposite direction. The shaft 170 is at rest, in which the sieve system, the cone and the tubes will be mounted. This axis that circles the area (169). The cleaning system 171 here is in reverse as here the jet will be top to bottom. In track 2 the distance is longer, so we get more inclined tracks for material separation.

Referring to figure 45, the same application as figure 44 can be seen, but in side view.

REÜVDMDOÜ

Claims (1)

DE (MtiMEKAllS1 ”; characterized in that it gathers in its functional constituent assembly the ability to process mud-shaped materials by pumping with a drop into a sieve; then into a silo that first feeds the conveyor whose belt is located. in concave shape carrying the mass of material starting the process, in this same belt the material is separated, and the heaviest material is concentrated in the middle of the belt, the first step of separation of the moving material occurs in the transition movement From the concave to flat belt, at this time the excess liquid is partially separated from the solids, when the belt becomes flat the liquid exits from the side of the belt and the heavier material continues in the process. the belt undergoes the transformation from flat to convex and inclined, raising the material and simultaneously initiates a vibration transverse action caused by lugs mounted on the sides of the belt; a spray amount is installed which directs water in the opposite direction of material movement, forming water slides over the classified material; later the belt that was already tumbling convexly increases the amplitude of its vibration, at this stage the water that was released in the opposite direction of the previous staps penetrates all the material, where the separation of materials begins. heavy from the lightest, the thickest from the thinnest, all at the same time and towards the belt; From that moment on the grains begin to move towards the sides of the belts due to their profile and inclination of the special mazes of the belt surface; With other forward mounted spray nozzles also directing water in the opposite direction of grain movement, we ensure a moving water film height required for grain separation, depending on the type of material being processed; along the lengths of the belts, we achieved using the same method as mentioned a separation of grain in sizes and weights concomitantly; the first separation is from materials that float along with water, the second is from lighter solid materials with smaller particle size range, the third is for solid materials of the same density with lower particle size range; The dimensions of the mineral classifier may change in their length, width and height depending on the material to be classified; The height of the power tower can be changed if the product power is dry.