DE1204601B - Upstream classifier - Google Patents

Description

Upflow classifier The invention relates to an upflow classifier, at which granular solids such as ores or other minerals classified or according to the weights are sorted in an upward flowing liquid and which are themselves any settable solids accumulating at the bottom of the classifier are discharged. Up to now, upflow classifiers have been used to classify or sort such solids used, in which the solids accumulating on the bottom as a fraction a lifter to be carried out. Usually the siphon was then constantly topped up with water to ensure the suction of the lifter. It was found that this constant supply of top-up water often dilutes the concentrated fraction and thereby .the efficiency of the classifier reduced.

It is therefore an object of this invention to provide an upflow classifier to design a lifting device that automatically regulates the inflow of the top-up water to the lifter regulates.

A second aim of the invention is to design the lifter discharge in such a way that that suction water is automatically supplied to the siphon when required and the suction water supply to the siphon is turned off when it is not required is. In addition, the desired coarse fraction should be discharged automatically from the system and safely regulated, with the solids to be classified in the system in the Mixture with liquid are supplied.

To solve this problem, the upflow classifier according to FIG. Invention, characterized by a supply line for dilution liquid to the inlet end of the siphon and one responsive to the density of the solid-liquid mixture Control device for the purpose of density-dependent control of the flow of dilution water is conductively connected by the line to the control valve.

The granular solid mixture to be separated is in the upflow classifier introduced in the form of a sludge and in the lower part is through a perforated plate a flow of liquid is led and divided so that it is above the perforated plate from the settling solids and the liquid "forms a fluidized bed column, to compare with a fluidized bed created by gas flowing upwards is. As a result of the hindered settling in the fluidized bed, accumulate with continuous Loading certain particles above the perforated plate; the coarser particles sink down on these, while the finer particles and the liquid as a result of the larger ones Dense, the fluidized bed rise to the top. The lifter dives with one of his thighs up to the vicinity of the perforated plate in the fluidized bed and preferably has at its lower end a bell by means of which the coarse fraction is captured and discharged is, for an effective operation of such an upflow classifier is a certain To choose the speed of the liquid upstream in order to ensure an undisturbed movement of the fluidized bed of particles of a certain size. This upflow velocity must be kept almost constant in order to obtain a certain solid fraction and carry out. An excess of water would reduce the velocity in the fluidized bed interfere and thus shift the separation limit.

In the classifier according to the invention, there is therefore preferably the control device consists of a sensing device for the pressure at the bottom of the solid-liquid mixture and a flow control valve in the line for the dilution water. aside from that are in the preferred embodiment a line for refill liquid for the lifter and a control device responsive to the pressure at the top of the lifter intended.

Details of the invention emerge from the description below of a preferred embodiment with reference to the drawing.

F i g. 1 shows schematically, partially in section, a single upflow classifier, with the automatic lift control; F i g. FIG. 2 is a circuit diagram shown in FIG. 1 control device used.

Into the container 10: the sludge or the like to be classified is introduced through line 12. A perforated plate 14 with holes 16 delimits a water chamber 18 at the bottom of the container, to which the water is fed through line 20 with valve 22. A valved drain line 24 -at the upper chamber 26 serves to completely empty the container 10, if this is desired. During normal operation, however, the line 24 is closed. An overflow channel 28 serves to discharge the finely divided fractions that do not settle in the container 10. An open-topped tube 30 protrudes into the chamber 26 to a point near the perforated plate 4. The pressure of the denser mass at this point causes the water in tube 30 to rise to a point which depends on the pressure at the lower end of the tube. A bellows 32 in open connection with the tube 30 expands and contracts according to the liquid level in the tube 30 and, when expanding, establishes a connection between the switch part 34 and the contacts 3.6, which connection is interrupted when contracted.

A siphon system 40 is used to remove the deposited fraction. It has a lower siphon bell 42, an ascending pipe limb 44 with a smaller diameter than 42 and a downwardly directed discharge trough 146. Leg 46 preferably has a smaller diameter than leg 44.

A three-way diaphragm valve 148 operated by a solenoid 56 is mounted in the discharge trough 146 to control the discharge of the coarse fraction. An air inlet conduit 50 and a suction conduit 52 are connected to two openings of the valve 48 for either admitting air into the zone around the diaphragm portion 54 through conduit 55 or evacuating it therefrom.

Dilution water from line 60 and top-up water from line 62 are fed to siphon bell 42 through line 58. The dilution water in line 60 is controlled by solenoid valve 64 with solenoid coil 66. The replenishment water in line 62 is controlled by solenoid valve 68 with solenoid coil 70.

At the top of the pipe leg 44, a bellows 72 is attached in open connection with the lifter 40 in order to sense the pressure therein. During normal operation of the lifter, bellows 72 will be contracted as a result of the negative pressure in the lifter, thus keeping switch 76 out of connection with contacts 78.

The shown - classifier works as follows: If the container 10 is filled with water and the water is continuously fed in through the line 20 and perforated plate 14 in a suitable amount, and the solids to be classified continue to be introduced through line 12 , it gradually forms at the bottom of the container from a fluidized bed. The resulting pressure at the lower end of the tube 30 pushes water into the interior of the bellows 32, which then expands and closes the contact 36 on the switch 34 : This closes the circuit to the solenoid valves 48, 64 and 68 . As shown in FIG. 2, the contacts 36 directly actuate coils 56 and 66 of the valves 48 and 64. In the position shown, valve 48 allows the air around the membrane portion 54 to escape through line 52 into the environment, the discharge limb 46 being opened. Simultaneously, actuation of valve 64 opens line 60 and allows dilution water to flow to siphon bell 42 so that the dislodged coarse particles can easily be siphoned off.

If the siphon has already been prepared for suction by filling it up, the settled solids come out of the siphon without the addition of water for preparation. The negative pressure in the lifter keeps the bellows 72 contracted so that the switch part 76 is lifted from the contacts 78 and line 62 is blocked for refill water.

If the siphon is not topped up during operation or start-up, bellows 72 will expand as the pressure in the siphon is higher than desired, causing switch 76 to connect contacts 78 so that valve 68 allows refill water to flow to the siphon. Once the lifter is operating properly, a vacuum is created in the lifter, lifting switch 76 from contacts 78 and stopping the flow of top-up water to lifter bell 42 .

Whenever the pressure in the vicinity of the perforated plate 14 falls below a certain value, bellows 32 contracts and breaks the contact between switch 34 and contacts 36, so that the circuit of the valves 48, 64 and 68 is interrupted. Valves 64 and 68 close lines 60 and 62 and solenoid coil 56 is de-energized, rotating valve 48 to position air line 50 connected to the area around diaphragm 54 and restricting the flow of solids in discharge leg 46.

It should be emphasized that the interruption of the circuit will reduce the inflow of refill or dilution water to the siphon switches off. This becomes an undesirable Changes in the fluidized bed speed prevented. This is especially true when low hydraulic velocities are used for classification.

The control system according to the invention is preferably electrical controlled, but it is within the scope of the invention, the valves pneumatically or hydraulically to regulate.

The membrane 54 can be switched on and off, which means the simplest and most direct regulation. Obviously, however, other means for regulating the discharge of fractions through the lifter leg46 can also be used. For example, an additional pressure sensitive switch that responds to the level of the liquid in the tube 30 can be used. A reverse control type valve would then be used in place of the three-way valve 48 . The pressure, which depends on the density at the bottom of the tube 30 and is sensed by the additional pressure-sensitive switch, is transmitted to the reverse control valve in order to regulate the coarse fractions as a function of the density in the vicinity of the perforated plate. In other words, air is supplied into line 50 in increasing amounts to move diaphragm 54 in the closing direction as the density decreases. Conversely, air is sucked in various amounts from the zone around the membrane 54 as the density increases in the vicinity of the perforated plate in order to allow the membrane to open.

The invention provides immediate automatic control of a Upflow classifier, which refills the siphon when necessary, and also one unwanted dilution of the settled fraction prevented when Navhfüllwasser is not necessary. It also ensures that no top-up water is supplied if the system does not work due to low pressure in the fluidized bed.

Claims (5)

Claims: 1. Upflow classifier, in which granular solids are classified or sorted according to weight in an upwardly flowing liquid mass and the settable solids that collect at the bottom of the classifier are discharged as a fraction through a lifter, characterized by a feed line (58) for dilution liquid to the inlet end (42) of the siphon (44, 46) and a control device ( 30, 32, 34) responsive to the density of the solid-liquid mixture, which for the purpose of density-dependent control of the flow of dilution water through the line (60) with the control valve (64, 66) is conductively connected. 2. Classifier according to claim 1, characterized in that -that the control device consists of a sensing device (30, 32, 34) for the pressure on Bottom of the solid-liquid mixture and a flow control valve (64) in the line (60). 3. Classifier according to claims 1 and 2, characterized through a line (62) for refill fluid for the lifter and one for the pressure control means (72, 76) responsive at the top of the lifter. 4. Classifier after Claim 3, characterized in that the control device (72, 76) for the refill liquid is connected in series with the control device (32, 36) in such a way that the supply of replenishing liquid when undershot a fixed density of the solid-liquid mixture is prevented. 5. Classifier according to Claims 1 to 4, characterized by a flow regulator (54, 48) in the siphon connected to the control device (32, 34, 64) for dilution liquid is connected in series. Considered publications German patents No. 446 086, 806 841.