RU2095154C1 - Flotation machine - Google Patents

Abstract

FIELD: mineral concentration; may be used in pulp flotation and in various chemical and technical processes. SUBSTANCE: flotation machine comprises cell, conical impeller connected with hollow shaft for air supply and drive. Impeller has projections on its side surface and disk with central hole and radial blades in its upper part. Impeller is located inside blade stator separated by disk with central hole into lower and upper parts. Impeller is installed in hole of stator disk with a clearance. Impeller disk is located above stator disk which is made for vertical motion along stator and its lower part has not more 6 blades. Outer diameter of stator disk is larger than outer diameter of stator blades. EFFECT: higher efficiency. 4 cl, 1 dwg

Description

 The invention relates to mineral processing and can be used for flotation of pulp, as well as in various chemical and technological processes.

 Known flotation machine (US Pat. USSR N 1512475, 03 D 1/16), including a cylindrical body, inside which is placed an impeller connected to the drive, made in the form of a truncated hollow cone with protrusions on the outer surface, facing a smaller base down, means for supplying air, a blade stator mounted around the impeller and mounted on a plate located under the impeller with a gap relative to the housing, as well as a device for supplying raw materials installed in the housing at the level of the impeller with the possibility vertical movement.

 This flotation machine allows you to select very large particles from the feed pulp, which are discharged into the pipe in the bottom of the body and sent to grinding and re-flotation.

 However, this machine is very energy-intensive due to the fact that the aeration unit is placed in the zone of high pulp density, i.e., it is necessary to spend a large amount of energy on pumping the pulp.

 Closest to the technical nature of the proposed machine is a flotation machine with aerator for ed. St. N 1217482, B 03 D 1/14, which is selected for the prototype.

 It contains a chamber, a drive, an aeration unit containing a hollow shaft for supplying air, a hollow truncated cone with protrusions on the side surface and a hole in the lower base mounted on the shaft, a disk with a central hole and radial blades, and a circulation device made in the form of a ring connected with radial blades of the aerator disk.

 A flotation machine with the specified aerator allows you to effectively float small pulp fractions (size from 0.074 mm to 0.1 mm) due to the intensification of bottom circulation of the pulp.

 However, this flotation machine does not provide efficient flotation of large particles of a useful product (size from 0.1 mm to 0.3 mm).

 The proposed flotation machine solves the problem of increasing the flotation efficiency due to flotation of both small and large fractions of a useful product by creating hydrodynamic flows that ensure the rise of the bottom product.

 In addition, the problem of regulating the circulation of the bottom and chamber product is solved, which ensures stabilization of the flotation machine.

 The specified technical result is achieved by the fact that the proposed flotation machine includes a chamber, a drive, an aeration unit containing an impeller made in the form of a truncated hollow cone connected with a hollow shaft for air supply with protrusions on the side surface facing down with a smaller base, containing a disk in the upper part with a central hole and radial blades.

 New in comparison with the prototype is that the proposed flotation machine contains a blade stator, separated by a disk with a central hole in the lower and upper parts, and the impeller is installed in the hole of the stator disk with a gap, while the impeller disk with radial blades is located above the stator disk.

 In addition, the stator disk is made with the possibility of vertical movement along the axis of the stator.

 In the lower part of the stator contains no more than six blades, and the outer diameter of the stator disk is larger than the outer diameter of the stator blades.

 The presence of a blade stator allows you to prevent twisting of the pulp flow, as well as to increase the degree of dispersion of air coming from the lower base of the impeller.

 The installation of a disk with a Central hole separating the stator on the upper and lower parts, and the location of the impeller in the hole of the stator disk with a gap to create a stream of pulp, capturing the bottom product and transporting it to the upper part of the chamber, located above the stator disk. When the conical impeller rotates, a zone of reduced pressure is formed in the annular gap between the stator disk and the side surface of the impeller.

 In this case, bottom circulation of the pulp is carried out. The pulp is sucked from below into the annular gap between the stator disk and the impeller, and is discharged into the chamber volume under the stator disk, dragging the bottom product into the area above the stator disk. In this case, both small and large fractions of the bottom product are captured.

 The presence of a disk with a central hole and radial blades in the upper part of the impeller leads to the formation of another pulp stream in the upper part of the chamber above the stator disk. It is formed when the impeller rotates, since the pulp from the upper part of the chamber is sucked in through the disk with the central hole and radial blades into the reduced pressure zone under the impeller disk, after which the pulp rushes into the upper part of the chamber.

 A stream formed by an impeller disk with radial blades runs onto a stream exiting the annular gap, forming high turbulence in the gap between the stator and the impeller. This provides a fine dispersion of air in the specified gap.

 Formed hydrodynamic flows allow flotation of both bottom and chamber product. The product particles entrained from the bottom are transferred by the flow formed by the stator disk and the impeller into the zone of intense dispersion of air leaving the hole in the lower base of the impeller located in the gap between the stator under the stator disk. Particles of a useful product are captured by air bubbles, transported upward by a stream circulating in the upper part of the chamber, and are discharged as a foam product.

 The flotation of the chamber product is carried out in a similar manner. A useful product from the upper volume of the chamber enters the zone of intense dispersion of air, where mineral particles are captured by air bubbles, and then transported upward and discharged as a foam product.

 The impeller disk with radial blades is located above the stator disk to ensure the stable formation of these hydrodynamic flows.

 The installation of a stator disk with the possibility of vertical movement along the axis of the stator provides adjustment of the circulation of the bottom and chamber product, creating a uniform density in the zone of intense air dispersion. Moreover, the higher the stator disk is installed above the bottom of the chamber, the stronger the bottom circulation and the more the bottom product is captured. The lower the stator disk is installed above the bottom of the camera, the less is the bottom product captured.

 The number of stator blades in its lower part under the disk is selected no more than six. To reduce the resistance to the movement of the pulp, the blades in the lower part of the stator act as a rectifier and contribute to organizing the direction of the bottom circulation in the direction of the annular gap between the stator disk and the impeller.

 The outer diameter of the stator disk is larger than the outer diameter of the stator blades in order to separate large pulp particles from the floated fractions. Moreover, the larger the outer diameter of the stator disk, the stronger the effect of separation of floated and larger particles.

 Large particles falling in the area above the stator disk fall down on the bottom of the chamber due to their loss of speed. Depending on the size of the outer diameter of the stator disk and the size of the annular gap between the stator disk and the side surface of the impeller, it is possible to control the size of the particles involved in the flotation.

 The drawing shows a sketch of the design of the proposed flotation machine.

 The flotation machine comprises a chamber 1, a conical impeller 2, facing down with a smaller base and connected to a hollow shaft 3 for air supply and a drive (not shown in the drawing). The impeller 2 contains protrusions 4 on the side surface, and in the upper part of the disk 5 with a Central hole and radial blades. Impeller 2 is located inside the blade stator 6, divided by a disk 7 with a central hole into the lower and upper parts. The impeller 2 is installed in the hole of the disk 7 of the stator 6 with a gap, while the disk 5 with the radial blades of the impeller 2 is located above the disk 7 of the stator 6. The disk 7 is made with the possibility of vertical movement along the stator 6.

 In the lower part of the stator 6 contains no more than six blades. The outer diameter of the disk 7 is larger than the outer diameter of the stator blades 6.

 Flotation machine operates as follows.

 Impeller 2 is driven by a drive (not shown in the drawing). When the impeller 2 is rotated, a zone of reduced pressure is created in the annular gap between the disk 7 and the side surface of the impeller 2. In this case, bottom circulation of the pulp is carried out. The pulp is sucked from below into the annular gap between the disk 7 and the impeller 2 and is discharged into the chamber above the disk 7. The specified flow carries the bottom product into the zone above the disk 7.

 In the upper part of the chamber 1 above the disk 7 of the stator 6 another stream of pulp is formed. The pulp is sucked from the upper part of the chamber 1 through the central hole of the impeller 2 with the radial blades of the impeller 2 into the reduced pressure zone under the impeller 2 of the disk 5, after which the pulp rushes into the upper part of the chamber 1. On the conical surface of the impeller 2 with the protrusions 4, air is dispersed through the hollow shaft 3 and emerging from the hole in the lower base of the impeller 2, the air is most intensely dispersed in the zone located in the gap between the stator 6 and the side surface of the impeller 2 above the disk 7. Particles d The bottom product, which, due to bottom circulation, has reached the region above the disk 7, is captured by air bubbles, transported upward by the flow circulating in the upper part of the chamber 1, and discharged as a foam product.

 Particles of the chamber product also fall into the zone of active dispersion of air, are captured by air bubbles, after which they are transported upward and discharged in the form of a foam product.

 The circulation of the bottom and chamber product is controlled by changing the vertical position of the disk 7 relative to the stator 6. The higher the disk 7 is installed above the bottom of the chamber 1, the stronger the bottom circulation and the more the bottom product is captured.

 The lower the disc 7 is mounted above the bottom of the chamber 1, the less is the bottom product captured.

 Since the number of stator blades 6 in the lower part is not more than six, the resistance to movement of the pulp in the lower part of the chamber decreases; this also contributes to the organization of the direction of the bottom circulation in the direction of the annular gap between the disk 7 and the impeller 2.

 Very large and heavy particles are not a useful product; they are carried by the flow of bottom circulation through the annular gap between the disk 7 and the impeller 2, but are not captured by air bubbles, but pass over the disk 7. Moreover, since the outer diameter of the disk 7 is larger than the outer diameter of the stator 6, then large particles lose speed and fall on the bottom of chamber 1.

 The proposed flotation machine allows you to effectively flotate both small and large fractions of a useful product due to providing capture of both bottom and chamber product. This ensures the adjustment of the ratio of the number of bottom and chamber product, as well as the adjustment of the size of floated particles and larger particles deposited on the bottom of the chamber, which ensures stabilization of the flotation of particle size.

 The use of the proposed flotation machine can increase the recovery of a useful product and achieve a reduction in energy consumption while maintaining high flotation rates.

Claims (4)

 1. A flotation machine including a chamber, a drive, an aeration unit containing an impeller made in the form of a truncated hollow cone connected with a hollow shaft for air supply with protrusions on the side surface, containing in the upper part a disk with a central hole and radial blades and facing a smaller base down, characterized in that the machine contains a blade stator, divided by a disk with a central hole into the lower and upper parts, and the impeller is installed in the hole of the stator disk with a gap, while the disk is impel A radial-bladed ra is located above the stator disk.  2. The machine according to p. 1, characterized in that the stator disk is made with the possibility of vertical movement along the stator.  3. The machine according to claim 1, characterized in that in the lower part of the stator contains no more than six blades.  4. The machine according to p. 1, characterized in that the outer diameter of the stator disk is larger than the outer diameter of the stator blades.