RU2108867C1 - Jigging classifying machine - Google Patents

Abstract

FIELD: concentration of minerals; wet gravitational extraction of gold nuggets and other noble metals from gravel deposits; classification of materials by sizes. SUBSTANCE: machine includes frame, chamber, drive, screen, double-arm lever connected with screen and drive which may perform incomplete revolution around fixed axle. Screen is provided with shoulders. One arm of lever is rigidly connected with screen or with its box to reduce horizontal amplitude and to increase vertical amplitude of vibrations along screen towards delivery of material. When vibration exciter is switched on, lever starts swinging to the right and to the left transmitting its vibrations to arm which starts rising or lowering. Screen executes similar motion. Material to be concentrated gets suspended when comes to the screen, disintegrated, separated by density, classified, after which it is dewatered and transported beyond chamber boundaries. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to mineral processing and can be used for wet gravity extraction of gold nuggets and other noble metals of placer deposits, as well as the classification of materials by size.

Known jigging machine containing a frame, a camera, a drive, a sieve connected to the sieve and the drive two-arm lever, which can make only an incomplete revolution around a fixed axis. A movable box with a sieve is suspended on shock absorbing springs. The drive mechanism informs the sieve in an arcuate motion with horizontal movement in the direction of ore loading during the sieve downward movement and feeding it forward when rising upward. As a result of this, loosening of the bed and promotion of the deposited material along the sieve are achieved simultaneously. The movement of the material in the direction of unloading the tails is also facilitated by a small slope (about 5 ^o ) of the box and the stepwise arrangement of the sieve sections. The heavy product is unloaded through slots in the sieve, adjustable with the help of handwheels (Handbook of ore dressing. M: Nedra, 1983, pp. 54-55 and Fig. 1.34). Adopted for the prototype.

The disadvantages of the prototype are as follows:
the sieve along the entire length has the same amplitude, therefore, the same power of the vibration field, which does not provide a sufficiently high deposition efficiency, especially at the material loading point. This makes it necessary to carry out a sieve of considerable length;
the location of the drive in the upper part of the machine increases its dimensions, metal consumption and makes manufacturing more expensive;
the connection of the cranked levers with the box of the sieve with the help of hinges cannot provide vibration fields non-uniform along the length of the working body, which also reduces the deposition efficiency;
additional power consumption for overcoming the efforts of shock absorbers;
the angle of inclination of the sieve down cannot provide dehydration of the material and its supply upward to the discharge side;
high water consumption for unloading jig tailings.

 The purpose of the invention is to eliminate all the disadvantages of the prototype by creating non-uniform vibration fields (amplitudes) along the sieve and expanding the scope of the jigging-classification machine by combining jigging operations, classifying the material by size, dewatering the jigging tails and transporting them up the sieve to the side unloading.

 The goal is achieved by the fact that the bottom of the sieve is equipped with thresholds for bed formation, and one of the arms of the lever is rigidly connected to the sieve or to the box of the sieve to create amplitudes that are non-uniform along the length of the sieve in two planes.

 The drawing schematically shows a General view of the machine.

The machine consists of a frame 1 in which the camera 2 is installed. The frame has a stand 3, in the upper part of which a two-arm lever 5 is mounted on the hinge 4, having a shoulder 6. A box 8 is attached to the shoulder 6 of the suspension 7. The box 8 has a removable sieve 9, equipped with removable sills 10. A connecting rod 13 of the vibration exciter is attached to the hinge 11 of the shoulder 12. The vibration exciter is fixed on the frame 1, but can also be fixed on the chamber 2. It is recommended to set the angle of inclination of the sieve within 3 - 15 ^o and depends on the enrichment quality required (classification, separation by density) and productivity, i.e., the angle is set up from the horizontal and is determined in each case, for each material being enriched. The amplitude of the sieve is regulated by the drive 14, the length of the suspensions 7 and the mixing of the suspensions 7 along the shoulder 6.

 The machine operates as follows.

 When the pathogen 14 is turned on, the lever 12 oscillates left and right and transfers its vibrations to the arm 6, which either rises or falls. Sieve 9 makes the same movement.

 The enriched material is fed to the sieve 9 in its rear part and since it oscillates in water, the material is weighed, disintegrated, segregated by density, classified and, dehydrated, transported outside the chamber 2.

 Lugs 10 provide bed formation on sieve 9, i.e. provide the sieve 9 in jigging mode. Outside the sills 10 and partially between the sills, the sieve 9 works like a screen.

 For efficient operation of the machine in a wide range of material fineness classes up to -50 mm, in each particular case there should be its own sieve amplitude 9 both in the vertical and horizontal planes. The proposed technical solution satisfies this requirement.

 To ensure the efficiency of extraction, classification and disintegration of the material, the sieve 9 should be in the water at about the same depth as shown in the drawing, i.e. immersion sieve 9 is recommended so that the sills 10 are in the water. The maximum length of the shoulder 12 is chosen by the designers for the following reasons: reduction of the center of gravity of the machine; reducing the size of the machine; decrease in metal consumption of the machine; power consumption; in terms of compactness, ergonomics and aesthetics. The most profitable from the point of view of reducing the center of gravity, metal consumption and size of the actuator 14 to install as shown in the drawing.

The optimal size of the two shoulders of the lever, shoulders 6 and 12 for specific cases, it is recommended to choose depending on the required magnitude of the amplitude. For example, for platinum-containing and tin-containing 3 sands, different amplitudes are required, since the density of waste rocks in both cases is 2.6 - 2.9 t / m ³ , cassiterite and its intergrowths are from 3 to 7 t / m ³ , and platinum 21 , 45 t / m ³ . Therefore, each specific case is specified experimentally.

The following formulas for determining the design parameters of the machine are offered for designers developing technological regulations:
amplitude in the vertical plane
A _y = r [sinα-sin (α-γ)];
amplitude in the horizontal plane
A _x = r [cos (α-γ) -cosα],
where γ is the angle of deviation of the shoulder 6 from the horizontal, deg;
α is the angle between the axis of the shoulder 6 and the radius of rotation of the determined sieve point, deg;
r is the radius of rotation of the point for which the amplitude is determined, mm.

It should be noted that the separation efficiency depends primarily on the magnitude of the amplitudes in the horizontal and vertical planes. The task of the sieve is to raise the particles higher and carry them further, i.e. ensure good loosening of the bed, and in the process of falling they are separated by density, and since in water the rate of fall of particles, for example gold with a density of 19 t / m ³ , is slightly higher than the fall of gangue, the gold particles fall on a sieve closer to the point of elevation, and empty breed further. This ensures high separation efficiency with high productivity of the original product. Moreover, the sieving efficiency of small particles reaches 96 - 98%, which is significantly higher than the screening of known screens.

Thus, increasing the vertical amplitudes in the direction of movement of the material and reducing the horizontal, we provide:
better loosening of the material on the sieve, and its separability in density in the direction of its movement;
long path and speed of passage of particles to the sieve;
better penetration of small particles to the surface of the sieve by increasing loosening as the material moves forward, which increases the efficiency of screening and extraction of overgrate gold up to 99 - 100%, since the sifted material does not interfere with separation, but helps to increase the loosening of the bed of material on the sieve, which also contributes to the recovery of the beneficial component.

 The proposed device is new, since it is not known from the prior art, has an inventive step, since it does not explicitly follow from the prior art; It is industrially applicable, as it was used in industry.

Claims (1)

 Jigging classification machine comprising a frame, a chamber, a drive, a sieve connected to a sieve and a drive with a two-arm lever, which can only complete an incomplete revolution around a fixed axis, characterized in that the sieve is equipped with sills, one of the arm of the lever is rigidly connected to the sieve or box sieves to reduce horizontal and increase the vertical amplitudes of oscillations along the sieve in the direction of material supply.