RU2758406C1 - Centrifuge with vortex drive and adjustable flow of cleaned liquid - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: invention relates to devices designed for the separation of liquid inhomogeneous systems using centrifugal forces. The centrifuge consists of a housing and a rotor, including a column and a drum. At the base of the housing there is a vortex chamber of the guide device of the hydraulic drive turbine with tangential channels. The lower spike of the column is located in its central non-flowing zone. A conical impeller of a radial-axial centrifugal turbine with radial channels is attached to the bottom of the column by a flange. At the periphery of the impeller, an annular cavity is formed at the exit from its channels. It is connected to the separating cavity of the rotor by a number of holes in the bottom of the column, as well as to the central channel in the lower spike of the column by sector cavities made at the end of the impeller. Due to this, the liquid at the outlet of the turbine stage is divided into two streams. One stream is cleaned in the rotor and removed from the centrifuge through its upper support. Its flow rate is regulated by a throttle. The other stream is drained back into the tank through the central channel in the lower spike of the column and the lower support.

EFFECT: invention makes it possible to increase the efficiency of separation by providing the possibility of regulating the flow of the cleaned liquid with a constant operating mode of the vortex hydraulic drive.

1 cl, 3 dwg

Description

The invention relates to devices designed to separate liquid heterogeneous systems using centrifugal forces, and can be used for cleaning oils, fuels, hydraulic and washing fluids from mechanical impurities and water during their regeneration, as well as directly during the operation of machines.

Known full-flow centrifuge with a vortex drive [Patent for invention RU 2725791 C1, B04B 1/02, B04B 3/00, B04B 9/06. Full-flow centrifuge with vortex drive / Snezhko A.V., Snezhko V.A. - application: 2019135898; 11/07/2019; publ. 06.07.2020. Bul. No. 19] for cleaning liquids, containing a housing with a base and a cover, a rotor placed inside it on bearings, including a drum, a column with channels for supplying and removing the liquid to be cleaned, a turbine-type hydraulic drive, consisting of a guide vane installed in the base of the housing under the rotor and an impeller attached to the rotor column. The hydraulic drive is a centrifugal radial-axial turbine. Its guide vane in the form of a vortex chamber has one or more tangential inlet channels and forms a rotating and conically diverging flow at the outlet from the central hole. The turbine impeller has blades and channels of the flow zone located at the same taper angle. Through them, the flow is introduced into the inner region of the rotor through a system of holes in the column. The outlet of the purified liquid from the rotor is carried out through the lower spike of the column, located in the central non-working zone of the vortex chamber.

The disadvantages of this centrifuge include the fact that the entire fluid flow used in the hydraulic drive must be cleaned. As the calculations and experiments have shown, for the effective operation of the vortex hydraulic drive, providing them with a high rotor speed, a sufficiently large fluid flow is required.

At the same time, the residence time of the contaminated flow in the centrifugal field of the rotor is reduced, which negatively affects the separation efficiency of the centrifuge. In addition, the axial velocity of the cleaned flow in the separating cavity of the rotor can be quite significant, which can lead to the washout of deposited contaminants from the inner walls of the rotor.

Therefore, the aim of the invention is to increase the efficiency of separation by adjusting the flow rate of the liquid to be cleaned through the separation zone of the rotor at a constant flow rate through the vortex hydraulic drive, which is necessary to obtain a high rotation speed.

This goal is achieved in that the fluid flow used in the hydraulic drive is split at the outlet of the turbine stage. In this case, part of the liquid is directed for cleaning into the separating cavity of the rotor, and its flow rate can be regulated. The other part is drained from the centrifuge back to the intake container.

In this regard, a centrifuge with a vortex hydraulic drive is proposed, which is a radial-axial centrifugal turbine with a guide vane in the form of a vortex chamber and an impeller with blades and channels located at an angle of conicity of the flow emanating from the guide vane. At the outlet from the channels of the turbine impeller, the liquid is divided into two streams. One stream is directed for cleaning into the rotor cavity through openings in its bottom and then discharged through the upper support with the possibility of regulating the flow rate by throttling. Another flow through additional channels in the impeller and the lower rotor spike, located in the non-flowing cavity of the vortex chamber, is drained back into the intake tank without cleaning.

FIG. 1 shows a diagram of a centrifuge, FIG. 2 is a section of the vortex chamber, FIG. 3 - section of the turbine impeller and two of its types.

The centrifuge consists of a body 1, its base 2, a cover 3 with an upper support 4, a rotor installed in them in bearings 5, including a column 6 and a drum 7, fastened with a nut 8. At the base 2 of the body 1 there is a vortex chamber 9 of the guide vane of the hydraulic drive turbine with several tangential inlet channels. The lower thorn of the rotor column, which rests on the bearing 5, passes through its central non-working zone. The conical turbine impeller 10 with radial channels of rectangular cross-section is installed in the lower part of the column 6. The wheel is fixed on the column shaft with a conical flange 11, which, together with the channels, forms the flow zone of the centrifugal radial-axial turbine. At the periphery of the turbine impeller 10, at the exit from its channels between the bottom of the column 6 and the flange 11, a peripheral annular cavity 12 is formed. It is connected to the separation cavity of the rotor by a number of holes 13 located respectively opposite the outlet from each channel of the turbine. In addition, at the end of the impeller there are sectoral channels 14, separated by radial ribs 15 (Figs. 1, 3). Thanks to them, the connection of the peripheral annular cavity 12 at the outlet of the turbine with the axial annular chamber between the turbine impeller 10 and the column 6 and further with the central outlet channel in the lower spike of the column located in the non-flowing zone of the vortex chamber 9 is provided.

The liquid from the separating cavity of the rotor is discharged through the system of radial channels formed by the drum cover 7 and the column 6, the central drilling in the upper spike of the column and the upper support 4 of the rotor. A valve 16 is installed in the line at the outlet of the upper support to regulate the flow rate of the liquid to be cleaned.

In addition, in the base 2 of the centrifuge housing, a drainage channel 17 is made to drain fluid leaks through the cylindrical seals of the vortex chamber 9 with the conical flange 11 of the turbine impeller 10, as well as the upper spike of the column 6 with the upper support 4.

The centrifuge works as follows. The liquid to be cleaned from the intake tank is pumped under pressure to the periphery of the vortex chamber 9 (Figs. 1, 2). Having passed the tangential channels of the vortex chamber 9, the flow swirls and spreads out in a conical layer from its upper central hole, entering the radial channels of the turbine impeller 10. In this case, the swirling flow interacts with the blades of the turbine wheel 10 and drives the rotor into rotation. At the outlet from the channels of the turbine stage in the peripheral annular cavity 12, the flow is divided into two parts.

One part of the liquid through holes 13 in the bottom of the column enters the separating cavity of the rotor and rushes upward along the axis of its rotation. In the upper part of the rotor, the liquid purified in the centrifugal field through the radial channels between the column 6 and the cover of the drum 7 is collected in the central bore of the upper thorn, from where it is discharged outside through the upper support 4 of the rotor.

Another part of the liquid from the peripheral annular cavity 12 through the sectoral channels 14 (Fig. 1, 3) between the turbine impeller 10 and the bottom of the column 6 enters the axial annular chamber of the turbine impeller 10. Then, through the radial drills, it enters the central channel of the lower spike of the column 6 and is discharged through the hole in the base 2 of the centrifuge body back into the intake container.

The balance between the flow rates of two flows of fluid at the outlet of the turbine stage of the hydraulic drive: purified and returned back to the intake tank is regulated by valve 16. This allows you to change the duration of purification and its efficiency depending on the physical properties of liquid heterogeneous systems, composition and degree of their contamination. In this case, the total flow rate of the liquid realized in the vortex hydraulic drive remains unchanged and necessary for a given rotor speed.

Claims (1)

A full-flow centrifuge with a vortex drive and an adjustable flow of the liquid to be cleaned, containing a housing with a base and a cover, a rotor placed inside it on bearings, including a drum, a column with channels for supplying and removing the liquid to be cleaned, a turbine-type hydraulic drive consisting of a guide vane installed in the base a housing under the rotor and an impeller attached to the rotor column, the hydraulic drive being a centrifugal radial-axial turbine; its guide vane in the form of a vortex chamber has one or more tangential inlet channels and forms a rotating and conically diverging flow at the outlet from the central hole, the turbine impeller has blades and channels of the flow zone located at the same taper angle, characterized in that at the outlet from the channels of the turbine impeller, the liquid is divided into two streams - one stream is directed for cleaning into the separation cavity of the rotor through the holes in its bottom and then discharged through the upper support with the possibility of regulating the flow rate by throttling, the other stream through additional channels in the turbine wheel and the lower rotor stud, placed in the non-flowing cavity of the vortex chamber, it is drained without cleaning back into the intake tank.

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