RU2262388C2 - Centrifugal machine for separation of multi-component mixtures with withdrawal of two liquid fractions and one solid fraction - Google Patents

Abstract

FIELD: metallurgy; methods of production of metals and metal alloys.

SUBSTANCE: the invention is pertaining to the field of a centrifuging and intended for separation of multi-component mixtures. The technical result is an increase of efficiency of separation and quality of liquid fractions removable from the centrifugal machine, maintenance of stability of quality indices of the liquid fractions in a mode of throughput of the centrifugal machine. The centrifugal machine according to the invention is equipped with a dividing - distributing device mounted on a trunnion on the side of the screw, two chambers of reception and withdrawal of the liquid fractions, in which there are pressure devices or devices of a liquid fractions withdrawal, and in the pressure line of the liquid fractions withdrawal there are a densimeter and a control valve. The invention presents two alternatives of the centrifuge.

EFFECT: the invention ensures increased efficiency of separation, improved quality of liquid fractions removable from the centrifuge, stability of the liquid fractions quality indices while the centrifuge is in a throughput mode.

5 cl, 5 dwg

Description

The invention relates to centrifugation and can be used in the separation of mixtures consisting of two or more liquid and one solid fraction.

Known centrifuge according to US Pat. RU 2032470, IPC 7 V 04 V 1/00, 04/10/1995, containing devices for outputting a light liquid phase in the form of vertical tubes, and the discharge radius of this phase is determined by the depth of penetration of such tubes.

The disadvantage of such a centrifuge is that with such a number of output devices (6-8 tubes) it is almost impossible to adjust one single level of drain in each of the tubes, and during operation the fastening of the tubes weakens and the radius of the drain changes.

Known centrifuge according to US Pat. DE 3344432, IPC 7 V 04 V 1/20, 06/20/1985 with the withdrawal of two liquid and one solid fractions, having a pin and containing a cylindrical or cylindrical-rotor with a screw, a device for introducing the mixture into the rotor and a device for withdrawing from the rotor light and heavy liquid fractions.

The disadvantage of this centrifuge is the lack of output at the same time both light and heavy liquid fractions in pressure mode. In this case, liquid fractions are removed through special channels; the cross-sections of these channels are limited due to the strength characteristics of the parts in which these channels are made, and with a change in the radius of the liquid phase, the cross-section of the channel changes, and therefore the quality of the two liquid fractions obtained on this centrifuge is very sensitive to variability in the composition of the feedstock and the performance of the centrifuge by suspension.

This centrifuge is the closest analogue of the claimed invention.

The objectives of the present invention are to increase the efficiency of separation of the mixture and the quality of the liquid fraction removed from the centrifuge by reducing the concentration of each of the liquid fractions in the other liquid fraction, ensuring the stability of the quality indicators of the liquid fractions practically in the capacity of the centrifuge, and also creating mechanisms for controlling the quality of the liquid fractions, transition to other quality indicators of these fractions without stopping the centrifuge.

These tasks are achieved in that in a centrifuge for separating multicomponent mixtures with the output of two liquid and one solid fractions, having a pin and containing a cylindrical or cylindrical-rotor rotor with a screw, a device for introducing the mixture into the rotor and devices for removing light and heavy liquid fractions from the rotor According to the first embodiment of the invention, a spacer separation device for mixtures is placed on the trunnion on the screw side. The trunnion has channels for outputting light and heavy liquid fractions, connecting the separation output device with a device for receiving a heavy liquid fraction located on the opposite side of the trunnion. An output device from the centrifuge of the heavy liquid fraction and a device for supplying the light liquid fraction to the output chamber of this fraction are installed on the output channel of the last device. In the outlet chamber of the light liquid fraction, a pressure disk of the outlet of this fraction is installed, and a densitometer and a control valve are mounted on the outlet line of the light liquid fraction.

The separation output device is a single part in which a cavity is made for receiving a light liquid fraction, channels for outputting this fraction and channels for receiving a heavy liquid fraction are combined into a common cavity. The device also contains disks for draining light and heavy liquid fractions and a disk separating the output light and heavy liquid fractions.

In a centrifuge for separating multicomponent mixtures with the output of two liquid and one solid fraction having a pin and containing a cylindrical or cylindrical rotor with a screw, a device for introducing the mixture into the rotor and devices for withdrawing light and heavy liquid fractions from the rotor, according to the second embodiment, on the axle on the auger side, a separation output device for the mixture is installed. The trunnion has channels for outputting light and heavy liquid fractions, connecting the separation device with a device for receiving a heavy liquid fraction, mounted on the opposite side of the trunnion. The device for receiving a heavy liquid fraction has a pocket for outputting a heavy liquid fraction in which a pressure disk for outputting a heavy liquid fraction is installed, as well as inclined channels connecting the trunnion channels for outputting a light liquid fraction to a pocket for outputting a light liquid fraction in which a pressure disk for outputting a light liquid fraction is installed liquid fraction. A density meter and a control valve are mounted on the discharge line of the heavy liquid fraction.

The separation output device of the centrifuge according to the second embodiment is made similar to the separation and distribution device according to the first embodiment.

In the case of using a centrifuge according to the second embodiment, a device is installed on the drainage channels of the separated liquid fractions, comprising a discharge chamber for heavy and light liquid fractions, in each of which a pressure device is installed. A density meter and a control valve are installed on each of the pressure lines.

The invention is illustrated by drawings.

Figure 1 shows a longitudinal section of a centrifuge (first option).

Figure 2 presents the separation output device (longitudinal section).

Figure 3 presents the design of the centrifuge, which provides for the withdrawal of a light liquid fraction in a pressureless, and a heavy liquid fraction in a pressure mode.

Figure 4 presents the second version of the centrifuge (longitudinal section).

Figure 5 is a General view of a centrifuge with a rotor.

On the inner surface of the trunnion 1 (Fig. 1), a separating output device 2 (Fig. 2) is installed on the screw side, which is a single part in which a cavity 3 is made for receiving a light liquid fraction with channels for outputting this fraction 4 and channels 5 for receiving a heavy liquid fraction, combined into a common cavity 6. The device contains three discs: a disk 7 for draining a light liquid fraction, a disk 8 for draining a heavy liquid fraction and a disk 9 separating the output light liquid fraction from a heavy liquid fraction. The working surface of the discharge of liquids from the disks 7 and 8 is made along the radius (figure 2). Moreover, the radius R _{2 of the} disk 8 differs from the radius R _{1 of the} disk 7 by the value Δ, which is determined by the formula

Δ = h × (ρ ₂ -ρ ₁ ) / ρ ₂ , where

ρ ₁ is the density of the light fraction,

ρ ₂ is the density of the heavy fraction.

The device 2 is attached to the trunnion 1 by a bolt (not shown in the drawing) through gaskets 10, 11 separating the output light liquid fraction from the heavy liquid fraction. In the trunnion 1, channels 12 for outputting a light liquid fraction and channels 13 for outputting a heavy liquid fraction are made.

On the opposite side of the pin 1 with a bolt (not shown) through the gaskets 14, 15, a device for receiving a heavy liquid fraction 16 is fixed, in which channels 17 are made for withdrawing a heavy liquid fraction from a centrifuge.

In the device 16, channels 18 are made connecting the channels 12 with a pocket for outputting a light liquid fraction. In the latter, a pressure disk 20 is installed for outputting a light liquid fraction. A density meter and a control valve (not shown) are installed on the output line of the light liquid fraction.

In the second version of the centrifuge (figure 4) on the inner surface of the journal 1 from the side of the screw installed separation output device 2, which is additionally presented in figure 2. This device is a single part in which a cavity 3 is made for receiving a light liquid fraction with channels for outputting this fraction 4 and channels 5 for receiving a heavy liquid fraction combined in a common cavity 6. This part has three disks: a disk 7, intended for draining the light liquid fraction, a disk 8 for draining the heavy liquid fraction and a disk 9 that separates the output light liquid fraction from the heavy liquid fraction. The working surfaces of the discharge of liquids from the discs 7 and 8 are made along the radius.

The device 2 is mounted on the trunnion 1 by a bolt (not shown in the drawing) through gaskets 10, 11 separating the output light liquid fraction from the heavy liquid fraction. In the trunnion 1, channels 12 for outputting a light liquid fraction and channels 13 for outputting a heavy liquid fraction are made.

On the opposite side of the journal 1 with a bolt (not shown) through the gaskets 14, 15, a device 16 is mounted for receiving a heavy liquid fraction. In the device 16, a pocket 21 is made, in which a pressure disk 22 for outputting a heavy liquid fraction is installed, and also inclined channels 23 are made connecting channels 12 to a pocket for outputting a light liquid fraction 24, in which a pressure disk 25 for outputting a light liquid fraction is installed. Moreover, the radii R ₃ , R ₄ , R _{5 are} made smaller than the radius R ₁ .

The centrifuge works according to the traditional scheme.

The mixture to be separated is fed into the rotating rotor 26 (Fig. 5). Under the influence of the field of centrifugal forces, the mixture is distributed along the rotor and is divided into sediment (solid fraction) and two liquid fractions: light and heavy. In this case, the light liquid fraction is located closer to the axis of the rotor, and the heavy fraction is located on the periphery. Sludge is discharged by auger 27.

The light liquid fraction through the disk 7 is discharged into the cavity 3 and then passes through the channels 4, 12 and 23 into the pocket 24 of the output of the light liquid fraction, from which it is discharged by the pressure disk 25. Then, through the channels 28, 29, the light liquid fraction is fed into the chamber 30 under pressure and an outlet pipe (not shown in the drawing).

The heavy liquid fraction is discharged through the disk 8 and through the channels 13 it enters the pocket 21 of the output of the heavy liquid fraction, from which it is discharged by the stationary stationary disk 22. Then, through the channels 31, 32, the heavy liquid fraction is fed into the chamber 33 and the outlet pipe 34 under pressure.

A density meter 35 and a control valve 36 are installed on the output line of the heavy liquid fraction (Fig. 5), and a density meter 37 and a control valve 38 are installed on the output pipe of the light liquid fraction.

Creating additional resistance by the control valve 36, fine-tuning the quality of the output heavy liquid fraction is carried out, and using valve 38, fine-tuning the quality of the output light liquid fraction is carried out.

Reconfiguration to other characteristics of the output heavy and light liquid fractions is carried out by adjusting the valves 36, 38 according to the readings of densitometers 35, 37.

Reconfiguration, fine-tuning the quality of the output heavy and light liquid fractions lead to a change in the values of the level of discharge of the light fraction R ₁ , the level of discharge of the heavy fraction R ₂ . In this regard, the values of the discharge levels R ₃ , R ₄ and R ₅ should be less than the discharge level of the light liquid fraction R ₁ .

Claims (5)

1. A centrifuge for separating multicomponent mixtures with the withdrawal of two liquid and one solid fractions, having a pin and containing a cylindrical or cylindrical-rotor with a screw, a device for introducing the mixture into the rotor and a device for withdrawing light and heavy liquid fractions from the rotor, characterized in that on the spigot from the auger side there is a separation output device, while in the spigot channels are made for outputting light and heavy liquid fractions, and on the opposite side of the spigot there is a device for receiving heavy fluid fraction, in which channels for withdrawing a heavy liquid fraction from a centrifuge are made, while in the device for receiving a heavy liquid fraction, channels are connected connecting channels for withdrawing a light liquid fraction in a pin with a pocket for outputting a light liquid fraction in which a pressure disk for outputting a light output is installed liquid fraction, moreover, a density meter and a control valve are installed on the output line of the light liquid fraction. 2. The centrifuge according to claim 1, characterized in that the separation output device is a single part in which a cavity for receiving a light liquid fraction, channels for outputting this fraction and channels for receiving a heavy liquid fraction are combined in a common cavity, wherein the device contains disks for draining light and heavy liquid fractions and a disk separating the output light liquid fraction from the heavy liquid fraction. 3. A centrifuge for separating multicomponent mixtures with the output of two liquid and one solid fractions, having a pin and containing a cylindrical or cylindrical-shaped rotor with a screw, a device for introducing the mixture into the rotor and devices for removing light and heavy liquid fractions from the rotor, characterized in that on the spigot from the auger side, a separation output device is installed, while in the spigot channels are made for outputting light and heavy liquid fractions, and on the opposite side of the spigot there is a device for receiving heavy fraction, in which a pocket for outputting a heavy liquid fraction is made with a pressure head disk for outputting a heavy liquid fraction installed in it, as well as inclined channels connecting channels for outputting a light liquid fraction axle with a pocket for outputting a light liquid fraction, in which a pressure disk for outputting a light liquid fractions, and a densitometer and a control valve are mounted on the discharge line of the heavy liquid fraction. 4. The centrifuge according to claim 3, characterized in that the separation output device is a single part in which a cavity for receiving a light liquid fraction, channels for outputting this fraction and channels for receiving a heavy liquid fraction are combined in a common cavity, wherein the device contains discharging disks of light and heavy liquid fractions and a disk separating the output light liquid fraction from the heavy liquid fraction. 5. The centrifuge according to claim 3 or 4, characterized in that the device forming the withdrawal chambers of heavy and light liquid fractions is installed on the channels for discharging the separated liquid fractions, and pressure devices are installed in each of the two chambers for discharging liquid fractions, while on each of pressure lines installed densitometer and control valve.

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