RU139650U1 - CENTRIFUGE FOR SEPARATION OF EMULSIONS - Google Patents

Abstract

1. A centrifuge for separating water-based emulsions, containing a rotor with a coalescing cartridge, inside which a perforated nozzle is coaxially placed, a shaft with emulsion supply and discharge channels of separated components - water and a light phase, a light phase chamber located on the inside of the nozzle in communication with the channel light phase outlet, sealing nodes of the emulsion supply channels and removal of separated components and a separated light phase sensor in the form of an electrode, characterized in that the electrode is mounted on the sealing node e channels of removal of the separated components in such a way that the sensitive part of the electrode is placed in the cavity of the channel for removal of the light phase. 2. A centrifuge according to claim 1, characterized in that the electrode is rod-shaped and placed coaxially in the cavity of the channel for withdrawing the light phase. 3. The centrifuge according to claim 1, characterized in that the light phase chamber is formed by an annular cavity between the inner surface of the perforated nozzle and the outer surface of the shaft, while the chamber is in communication with the emulsion supply channels.

Description

The utility model relates to centrifuges with a rotating rotor, designed to separate water-based emulsions containing a dispersive light phase of organic origin in the form of finely divided drop oil, oil products, fats, etc.

A known centrifuge (a device for purifying water from oil products, SU 700162 A1, publication 11/30/1979), containing a rotor with a volumetric coalescing cartridge, a shaft with channels for supplying the original contaminated liquid and removing separated components - water and light phase. In the known device, the inlet openings of the channels for withdrawing the light phase are located in the peripheral zone of the rotor in the immediate vicinity of the channels for draining the separated water. The proximity of these channels determines the conditions for repeated mixing of water and separated oil products and the deterioration of the quality of separation.

The closest analogue of the proposed utility model is a centrifuge (separator) for separating a water-oil emulsion containing a rotor with a volumetric coalescing cartridge and with a coaxial perforated nozzle, an upper half shaft with an emulsion feed channel into the rotor, a lower half shaft with a water drain channel located inside the perforated light pipe chamber phase communicated with the channel for the removal of light phase, stationary sealing cartridges of the channels for supplying emulsion and removal of the separated components, as well as the sensor separately light phase discharge valves connected to the control unit of the water and the lighter phase (SU 944670 A1, publication 07.23.1982). In the known centrifuge, the sensor of the separated light phase is an accessory of the rotor and is made in the form of ring electrodes that are mounted on the upper half shaft and placed inside the light phase chamber. This sensor has a structurally difficult electrical connection with the control unit by means of a collector mounted on the end surface of the rotor and a brush device. In addition to the structural complexity, the presence of a brush device imposes restrictions on the possibility of using a centrifuge in hazardous areas. The placement of the sensor of the known device inside the chamber of the light phase leads to the need to increase the volume of this chamber by reducing the volume of the coalescing cartridge, which in turn leads to a decrease in the throughput of this centrifuge. In addition, in the known device, the outlet openings of the emulsion supply channels to the coalescing cartridge are directly adjacent to the inner surface of the perforated nozzle, which leads to an uneven distribution of the fluid flow over the volume of the coalescing cartridge and, as a result, to deterioration of the phase separation conditions of the emulsion.

The technical task of the utility model is to simplify the design, increase throughput and separation efficiency.

The problem is solved in that in a centrifuge for separating emulsions on a water basis, containing a rotor with a coalescing cartridge, inside which a perforated nozzle is coaxially placed, a shaft with channels for emulsion supply and removal of separated components - water and a light phase, a light chamber placed on the inside of the nozzle phase communicated with the channel for withdrawing the light phase, the sealing nodes of the channels for supplying the emulsion and removal of the separated components and the sensor of the separated light phase in the form of an electrode, according to the proposal The electrode is mounted on the sealing assembly of the channels for removing the separated components in such a way that the sensitive part of the electrode is placed in the cavity of the channel for removing the light phase.

In a preferred embodiment, the electrode is made rod and placed in the cavity of the channel for removal of the light phase coaxially.

Fixing the sensor on a stationary cartridge, making the sensor in the form of an electrode, the sensitive part of which is placed in the cavity of the light phase channel, provides the technical result of the invention — simplifying the design by eliminating the use of complex electrical communications in the form of a collector and brush device, makes it possible to reduce the volume of the camera light phase and increase centrifuge throughput.

In addition, the implementation of the chamber of the light phase in the form of an annular cavity between the inner surface of the perforated nozzle and the outer surface of the shaft and the communication of the chamber with the emulsion supply channels makes it possible to ensure uniform flow in the volume of the coalescing cartridge and significantly improve the conditions for phase separation.

The essence of the proposed utility model is illustrated using the drawing.

The centrifuge contains a rotor 1 with a volumetric coalescing cartridge 2, a shaft 3 with channels 4 for supplying the emulsion to the rotor and with channels 5 and 6 for removing the separated components - water (5) and light phase (6). In the inner cavity of the rotor 1 there is a coaxial perforated pipe 7, inside of which there is a light phase chamber 8 connected with the channel 6. To seal the channels, the sealing assemblies are stationary cartridges 9 and 10. To ensure the discharge of the separated light phase from the rotor, the control unit 11 electrically connected to the sensor 12 of the light phase. The sensor 12 is mounted on the housing of the cartridge 10 and is preferably made in the form of a rod electrode, the sensitive part of which is placed coaxially in the cavity of the channel 6 for removal of the light phase. The light phase chamber 8 is formed by an annular cavity between the inner surface of the pipe 7 and the outer surface of the shaft 3, while the cavity is in communication with the emulsion supply channels 4. To dump the separated light phase from the chamber 8, an automatic valve 13 is used, which is installed on the line for withdrawing the light phase from the cavity of the stationary cartridge 12 and is electrically connected to the control unit 11.

The proposed centrifuge operates as follows.

The initial emulsion through the cartridge 9 and channel 4 enters the annular chamber 8 and then is evenly distributed throughout the volume of cartridge 2. Under the influence of the coalescing properties of cartridge 2, small droplets of light phase are enlarged, which, under the action of the centrifugal field of the rotor rotor 1, enter the chamber 8. Purified water is withdrawn from the rotor 1 through the channel 5 and then through the cartridge 10. As the light phase accumulates in the chamber 8, the heavier phase is displaced from the cavity of the channel 6 and filled with its light phase. As a result, there is a change in the electrical conductive properties of the liquid, which leads to the actuation of the sensor 12 and the formation of a signal to the control unit 11. The control unit 11 provides a pulse to open the valve 13, which provides a discharge of the light phase from the chamber 8.

Claims (3)

1. A centrifuge for separating water-based emulsions, containing a rotor with a coalescing cartridge, inside which a perforated nozzle is coaxially placed, a shaft with emulsion supply and discharge channels of separated components - water and a light phase, a light phase chamber located on the inside of the nozzle in communication with the channel light phase outlet, sealing nodes of the emulsion supply channels and removal of separated components and a separated light phase sensor in the form of an electrode, characterized in that the electrode is mounted on the sealing node e channels of removal of the separated components in such a way that the sensitive part of the electrode is placed in the cavity of the channel for removal of the light phase. 2. The centrifuge according to claim 1, characterized in that the electrode is made of a rod and placed coaxially in the cavity of the channel for removal of the light phase. 3. The centrifuge according to claim 1, characterized in that the light phase chamber is formed by an annular cavity between the inner surface of the perforated nozzle and the outer surface of the shaft, while the chamber is in communication with the emulsion supply channels.

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