CA1116321A - Froth flotation cell - Google Patents
Froth flotation cellInfo
- Publication number
- CA1116321A CA1116321A CA000323265A CA323265A CA1116321A CA 1116321 A CA1116321 A CA 1116321A CA 000323265 A CA000323265 A CA 000323265A CA 323265 A CA323265 A CA 323265A CA 1116321 A CA1116321 A CA 1116321A
- Authority
- CA
- Canada
- Prior art keywords
- tank
- pulp
- cell
- froth
- impeller
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Landscapes
- Paper (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE
Coarse particles of up to 3 mm are floated in a cylindrical froth flotation cell in which the agitation impeller has a cover preventing fluid from being drawn in above. Air is supplied from a ring around the periphery of the cell and situated above the cover. Baffles project radially inwardly up to a short distance from the top. Froth is allowed to overflow around the periphery of the cell. The opposed inlet and outlet are disposed at the level of the impeller. The arrangement is such that the liquid below the layer of froth is substantially quiescent.
Coarse particles of up to 3 mm are floated in a cylindrical froth flotation cell in which the agitation impeller has a cover preventing fluid from being drawn in above. Air is supplied from a ring around the periphery of the cell and situated above the cover. Baffles project radially inwardly up to a short distance from the top. Froth is allowed to overflow around the periphery of the cell. The opposed inlet and outlet are disposed at the level of the impeller. The arrangement is such that the liquid below the layer of froth is substantially quiescent.
Description
- 2 -Background of the Invention ~ THIS invention relates to a froth flotation cell.
., "~
~, " .~
The present invention arose from the requirement of having to separate mineral particles as large as - 3 mm by means of froth flotation.
, Flotation from - 3 mm feeds is unusual. In fact flotation feeds seldom exceed 250 microns for metal ores.
Summary of the Invention According to the invention a method of recovering coarse particles by froth flotation comprises agitating a conditioned pulp, to which a suitable frother and collectorhave been added, for turbulent vertical ; flow, injecting air bubbles into the path of pulp flow in such a way that the only size~ reduction of the bubbles is due to shear~by the pulp, baffling the pulp flow to ensure a quiescent interface between pulp and froth, and collecting the froth from the interface.
~ ~ The method also includes the steps of introducing pulp to and withdrawing ;~; the pu1p from the system in d zone of relative pu1p agitation.
According to the invention a flotation cell comprises a tank, a driven impeller at a low level in the tank, a cover above the impeller minimizing the entry of fluid from above, and a series of injec~ion points for co~,pressed air around the axis of the tank and above the level of the cover.
.0 Further according to the invention the tank is round cylindrical and over,low of froth is around the entire perimeter of the top of the ta , ,.
~;3'~
The invention also provides that the tank has a series of radial ax;ally extending ba~fles projecting inwardl~y from the periphery of the tank.
Furthermore the invention provides that pulp be fed into the tank below the stagnation zone of the radial flow from the impeller and that it be withdrawn from the t;nk in that zone.
Description of the Drawing It is a section through a froth flotation cell according to the invention.
Description of a Preferred Embodiment - The illustrated cell has a round cylindrical tank 10 in the bottom of which there is a driven impeller 12 rotated by means of a shaft 11. The . impeller 12 has four radial vanes and is of standard design. However, above the impeller 12 there is a cover 13 which reduces the entry of , air into the impeller 12 from above. ~~
The tank 10 has an overflow launder l~ around its entire ~op perimeter for collecting froth.
, At a 1evel above the cover 13 there is a ring main 15 for injecting com-pressed air into the tank 10. ~ ~
An inlet pipe 16 leads to a level below the impeller 12 and an outlet 18 leads from the same level as ~he impeller 12. Note that the outlet 18 is from,the annular stagnation zone of the radial flow from the impeller 12 while the inlet 16 leads to a level below that zone.
2Q ~ A series of baffles l7 project radially inwardly -from,the w,all of the tank 10. The axial extent and the radially inward extent of the baffles 17 require adjustment for various circumstances to ensure that at the top of the tank there is a quiescent pulp-froth interface. It has been found beneficial to have the upper parts or the baffles 17 inclined to the vertical. The angle of inclination may be between 10 and 45. The ``
63'~
direction of inclination is so chosen that, when viewed from above, the inclined sections of the baffles spiral downwardly in the same direction as the direction of rotation of the impeller.
Air is injected from the ringmain lS where the turbulence created by the radial flow from the impeller hitting the wall of the tank 10 provides some shear to reduce the size of the air bubbles and the rotational flow created by the impeller helps to ca`rry the air bubbles radially inwards towards the centre of the tank so that they are reasonably well distribu'ced.
~;~ Sincé the air enters the cell through the ringmain 15 which is situated -~ l0 above the cover 13,` and since the movement of air is generally up~ards, ;~ there~is little tendency for~air to enter the volume swept by the impeller, thus ensuring that the impeller performs its primary function of maintaining the particles-in suspension.
Since the shear forces which produce the bubbles are lower than they are ~ in the conventional cell in which air~is introduced into the impeller zone with a consequent drop in mixing efficiency, the air bubbles produced~ - -are~larger and thus better suited to the flotation of particles of a size for which~the cell is intended.
The circular overflow weir formed by the top of the tank~lO maximlses the ~ potentlal length of~the~weir, Experimental Results.
Thus far tests on a prototype cell have been restricted to sizes up to 20~ However, gold and~other valuable constituents of a Witwatersrand ore have been floated successfully from - 2,5 mm~material over pulp densities ranging from l5 to 55% solids by~mass without sanding out ~ taking place. Varying the pulp density has~been found to have only a very slight effect on air demand, power requ;remènts and rate of flotation.
: :~ :: - :
-Example :~ As an example of the use of the cell, qold and uranium were floated from ~ . .
, tf~
a material grading 100% - 2,36 mm 50% - 150 microns in three different types of cell. The conditions of flotation were the same in each case, namely 35% solids, 9 minutes batch flotation, and 100 g of potassium amyl xanthate and 50 g of AF 55 frother added per ton of solids, the additions ~e;ng made in the ratios 5:3:2 at the start, after 3 minutes and after 6 minutes vf flotation respectively. The three cells were a laboratory Fagergren machine normally of 5~ capacity, but reduced to 1,7 for the purposes of the test, operated at a power density equivalent to 35 kW/m3; a 20Q cell to the design described herein, operated a~ a power density equivalent to 10 kW/m3 excluslve of the power required for com-pressing air (30Q/min at a pressure of 25kPa); and a 170 ~ Fagergren cell operated at a power density equivalent to 15 kW/m3. The 170Q cell required manual stirring to prevent sands building up to the point where the impeller stalled. The results may be summarised as follows:-.
Cell 1,7~ 20~ 170 % Solids in feed 35 35 35 Power density kW/m3 35 10 15 % of solids in feed floated 33,1 34,2 18,5 % of gold in feed floated 82,6 86,2 42,7 ~ 20 % of uranium in feed floated 68,4 70,8 59,3 (~ ~ It ;s apparent that the novel cell suspends the coarse solids at a far lower power than conventional cells, and that it can yield at least as good a récovery of valuable minerals as in conventional cells, when the conventlonal cells are operated under conditions which suspend the coarse solids satisfactorily :: :
, :
., "~
~, " .~
The present invention arose from the requirement of having to separate mineral particles as large as - 3 mm by means of froth flotation.
, Flotation from - 3 mm feeds is unusual. In fact flotation feeds seldom exceed 250 microns for metal ores.
Summary of the Invention According to the invention a method of recovering coarse particles by froth flotation comprises agitating a conditioned pulp, to which a suitable frother and collectorhave been added, for turbulent vertical ; flow, injecting air bubbles into the path of pulp flow in such a way that the only size~ reduction of the bubbles is due to shear~by the pulp, baffling the pulp flow to ensure a quiescent interface between pulp and froth, and collecting the froth from the interface.
~ ~ The method also includes the steps of introducing pulp to and withdrawing ;~; the pu1p from the system in d zone of relative pu1p agitation.
According to the invention a flotation cell comprises a tank, a driven impeller at a low level in the tank, a cover above the impeller minimizing the entry of fluid from above, and a series of injec~ion points for co~,pressed air around the axis of the tank and above the level of the cover.
.0 Further according to the invention the tank is round cylindrical and over,low of froth is around the entire perimeter of the top of the ta , ,.
~;3'~
The invention also provides that the tank has a series of radial ax;ally extending ba~fles projecting inwardl~y from the periphery of the tank.
Furthermore the invention provides that pulp be fed into the tank below the stagnation zone of the radial flow from the impeller and that it be withdrawn from the t;nk in that zone.
Description of the Drawing It is a section through a froth flotation cell according to the invention.
Description of a Preferred Embodiment - The illustrated cell has a round cylindrical tank 10 in the bottom of which there is a driven impeller 12 rotated by means of a shaft 11. The . impeller 12 has four radial vanes and is of standard design. However, above the impeller 12 there is a cover 13 which reduces the entry of , air into the impeller 12 from above. ~~
The tank 10 has an overflow launder l~ around its entire ~op perimeter for collecting froth.
, At a 1evel above the cover 13 there is a ring main 15 for injecting com-pressed air into the tank 10. ~ ~
An inlet pipe 16 leads to a level below the impeller 12 and an outlet 18 leads from the same level as ~he impeller 12. Note that the outlet 18 is from,the annular stagnation zone of the radial flow from the impeller 12 while the inlet 16 leads to a level below that zone.
2Q ~ A series of baffles l7 project radially inwardly -from,the w,all of the tank 10. The axial extent and the radially inward extent of the baffles 17 require adjustment for various circumstances to ensure that at the top of the tank there is a quiescent pulp-froth interface. It has been found beneficial to have the upper parts or the baffles 17 inclined to the vertical. The angle of inclination may be between 10 and 45. The ``
63'~
direction of inclination is so chosen that, when viewed from above, the inclined sections of the baffles spiral downwardly in the same direction as the direction of rotation of the impeller.
Air is injected from the ringmain lS where the turbulence created by the radial flow from the impeller hitting the wall of the tank 10 provides some shear to reduce the size of the air bubbles and the rotational flow created by the impeller helps to ca`rry the air bubbles radially inwards towards the centre of the tank so that they are reasonably well distribu'ced.
~;~ Sincé the air enters the cell through the ringmain 15 which is situated -~ l0 above the cover 13,` and since the movement of air is generally up~ards, ;~ there~is little tendency for~air to enter the volume swept by the impeller, thus ensuring that the impeller performs its primary function of maintaining the particles-in suspension.
Since the shear forces which produce the bubbles are lower than they are ~ in the conventional cell in which air~is introduced into the impeller zone with a consequent drop in mixing efficiency, the air bubbles produced~ - -are~larger and thus better suited to the flotation of particles of a size for which~the cell is intended.
The circular overflow weir formed by the top of the tank~lO maximlses the ~ potentlal length of~the~weir, Experimental Results.
Thus far tests on a prototype cell have been restricted to sizes up to 20~ However, gold and~other valuable constituents of a Witwatersrand ore have been floated successfully from - 2,5 mm~material over pulp densities ranging from l5 to 55% solids by~mass without sanding out ~ taking place. Varying the pulp density has~been found to have only a very slight effect on air demand, power requ;remènts and rate of flotation.
: :~ :: - :
-Example :~ As an example of the use of the cell, qold and uranium were floated from ~ . .
, tf~
a material grading 100% - 2,36 mm 50% - 150 microns in three different types of cell. The conditions of flotation were the same in each case, namely 35% solids, 9 minutes batch flotation, and 100 g of potassium amyl xanthate and 50 g of AF 55 frother added per ton of solids, the additions ~e;ng made in the ratios 5:3:2 at the start, after 3 minutes and after 6 minutes vf flotation respectively. The three cells were a laboratory Fagergren machine normally of 5~ capacity, but reduced to 1,7 for the purposes of the test, operated at a power density equivalent to 35 kW/m3; a 20Q cell to the design described herein, operated a~ a power density equivalent to 10 kW/m3 excluslve of the power required for com-pressing air (30Q/min at a pressure of 25kPa); and a 170 ~ Fagergren cell operated at a power density equivalent to 15 kW/m3. The 170Q cell required manual stirring to prevent sands building up to the point where the impeller stalled. The results may be summarised as follows:-.
Cell 1,7~ 20~ 170 % Solids in feed 35 35 35 Power density kW/m3 35 10 15 % of solids in feed floated 33,1 34,2 18,5 % of gold in feed floated 82,6 86,2 42,7 ~ 20 % of uranium in feed floated 68,4 70,8 59,3 (~ ~ It ;s apparent that the novel cell suspends the coarse solids at a far lower power than conventional cells, and that it can yield at least as good a récovery of valuable minerals as in conventional cells, when the conventlonal cells are operated under conditions which suspend the coarse solids satisfactorily :: :
, :
Claims (7)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A method of recovering coarse particles by froth flota-tion comprising: agitating a conditioned pulp, to which a suitable frother and collector have been added, for turbulent vertical flow, injecting air bubbles into the path of pulp flow in such a way that the only size reduction of the bubbles is due to shear by the pulp, baffling the pulp flow to ensure a quiescent interface between pulp and froth, and collecting the froth from the interface.
2. The method claimed in claim 1 including the step of introducing pulp to and withdrawing the pulp from the system in a zone of relative pulp agitation.
3. A froth flotation cell comprising: a tank, a driven impeller at a low level in the tank, a cover above the impeller minimising entry of fluid from above, and a series of injection points for compressed air around the axis of the tank and above the level of the cover.
4. The cell claimed in claim 3 in which the tank is round cylindrical and overflow of froth is around the entire perimeter of the top of the tank.
5. The cell claimed in claim 3 in which the tank has a series of radially extending baffles projecting inwardly from the periphery of the tank.
6. The cell claimed in claim 5 in which the upper parts of the baffles are inclined to the vertical at an angle of 10° to 45°, the direction of inclination being so chosen that, when viewed from above, the inclined sections of the baffles spiral downwardly in the same direction as the direction of rotation of the impeller.
7. The cell claimed in claim 3 including an inlet to the tank below the stagnation zone of the radial flow from the impeller and an outlet to the tank from the same zone opposed to the inlet.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000323265A CA1116321A (en) | 1979-03-09 | 1979-03-09 | Froth flotation cell |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000323265A CA1116321A (en) | 1979-03-09 | 1979-03-09 | Froth flotation cell |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1116321A true CA1116321A (en) | 1982-01-12 |
Family
ID=4113723
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000323265A Expired CA1116321A (en) | 1979-03-09 | 1979-03-09 | Froth flotation cell |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA1116321A (en) |
-
1979
- 1979-03-09 CA CA000323265A patent/CA1116321A/en not_active Expired
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US4247391A (en) | Froth flotation cell and method of operation | |
CA1318730C (en) | Method of separating carbonaceous components from particulate coal containing inorganic solids and apparatus therefor | |
AU596924B2 (en) | Improved froth flotation method and apparatus | |
US3446353A (en) | Method and apparatus for froth flotation | |
US5702612A (en) | Method and apparatus for flotation separation | |
EP0272107B1 (en) | Aeration apparatus | |
CN1330426C (en) | Auxiliary agitator for a flotation device | |
US5855769A (en) | Apparatus and method for selective separation of hydrophobic material | |
AU2019100828A4 (en) | Flotation line | |
AU2019100827A4 (en) | Flotation cell | |
ZA200504796B (en) | Guiding device for a flotation machine. | |
US3730341A (en) | Flotation of coarse particles | |
CA1116321A (en) | Froth flotation cell | |
CN210434689U (en) | Forced circulation quick flotation separation device | |
US2591830A (en) | Recovery of resins from coal | |
CN113198619B (en) | Coarse particle flotation equipment and method adopting rotational flow and damping coupled fluidization | |
US3802569A (en) | Flotation machine | |
GB2093735A (en) | Froth flotation | |
US5611917A (en) | Flotation cell crowder device | |
US6772885B2 (en) | Rotor for flotation mechanism and method for directing material flow in flotation machine | |
CN113578515B (en) | Protective sorting equipment and method for large-scale graphite | |
US2148445A (en) | Method and apparatus for diffusion control | |
AU2019273043B2 (en) | Froth flotation apparatus | |
CN112090594A (en) | Nano-bubble flotation machine | |
US4406782A (en) | Cascade flotation process |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
MKEX | Expiry |