RU116794U1 - CENTRIFUGA FOR CLEANING LIQUIDS - Google Patents

Abstract

A centrifuge for cleaning liquids, containing a rotor with upper and lower seals and with a package of alternating conical plates and spacer washers placed inside it, equipped with a protective casing, and a drive motor, fixed on a common base and connected by a V-belt transmission, characterized in that it is additionally equipped a rotor rotation indicator placed on the protective casing, consisting of two receiving tubes, a housing with a diaphragm and a microswitch mechanically connected to it, and the receiving tubes with their open ends are placed in diametrically opposite sections of the annular gap between the protective casing and the rotor, conical plates and spacer washers are made with six holes forming three channels for supplying and three channels for removing liquid, while the holes in the conical plates are closed, and the holes in the spacer washers have through one through cutouts along the periphery, and the spacer washers are installed in the pack those in such a way that in each channel the closed holes alternate with holes with cutouts along the periphery, and the adjacent conical discs differ in outer diameter by a multiple of the thickness of the spacer washer.

Description

The utility model relates to centrifuges for fine purification of liquids from contaminants, for example, in test benches, in the hydraulic systems of airplanes, ships and other vehicles, when producing highly pure petroleum products, as well as for clarifying suspensions with a low concentration of impurities.

Known centrifuges for cleaning liquids containing a vertically placed rotor and a drive motor, mounted on a common base and interconnected by a V-belt drive. Such is, for example, a centrifuge for cleaning liquid, containing a vertically placed rotor with a package of inserts with upper and lower seals installed inside it, and a drive motor mounted on a common base and interconnected by a V-belt drive (see the book by P. Belyanin Centrifugal cleaning of working fluids of aircraft hydraulic systems. M., Me, 1976, p. 240, Fig. 161).

Continuous centrifuges are known comprising a housing, devices for supplying and discharging liquid, and a rotor with a drive, consisting of alternating conical perforated filter plates and continuous spacers for draining liquid. The disadvantage of such centrifuges is structurally and technologically difficult to perform elements that ensure an unstressed transition of particles of contaminants from one separation plate to another and the absence of an alarm about the rotation of the rotor, which does not guarantee the prevention of breakthrough of incompletely separated contaminants into the output line of the centrifuge (see RF Patent No. 2191635 MKI5 class B04B 3/00, published on October 27, 2002).

Centrifuges are also known in which the package of inserts contained inside the rotor is formed by alternating conical plates with openings on the base and spacer washers with through cuts along the periphery with the formation of an inter-tray space between the conical plates (see AC No. 581997, MKI2 B04B 1/04, 1977 ) In these centrifuges, the liquid is freed from contamination due to the short-term passage of the flow through the zone of maximum influence of the gravitational field on the periphery of the rotor inside these inter-tray spaces.

The disadvantage of such centrifuges is that through cutouts in the spacer washers connect each inter-tray space with both the liquid supply line and its drain line. Thus, a significant part of the fluid can only move within the inter-tray space, without going to the periphery of the rotor, which reduces the cleaning efficiency.

The closest in technical essence to the claimed utility model is a centrifuge containing a rotor, a feeding device and a package of conical plates, between which rings are installed, having holes and cutouts for forming channels for supplying and discharging liquid. (See AC No. 1132883, MKI4 B04B 1 / 08, 1985). We selected this centrifuge for the prototype.

The disadvantage of this centrifuge is the presence of additional slotted filters formed by cutouts in the rings for supplying the suspension to the plate package from the feeder. When the thickness of the plates and rings is in the range of 0.3-0.5 mm, which is currently the case in practice, such filters quickly clog and reduce the efficiency of the centrifuge. The absence of an alarm about the rotation of the rotor also creates a danger of the emission of contaminants when the separating centrifugal factor ceases to act.

The objective of the claimed utility model is to increase the efficiency of separation of contaminants from the fluid stream and their removal by separation with simultaneous control of the fact of rotation of the centrifuge rotor.

This task is realized in such a way that a centrifuge for cleaning liquids, containing a rotor with upper and lower seals and with a package of alternating conical plates and spacers placed inside it, equipped with a protective casing, and a drive motor mounted on a common base and interconnected by a V-belt the gear is equipped with an additional rotor rotation warning device located on the protective casing, consisting of two receiving tubes, a housing with a diaphragm and mechanically connected to it microswitches, and the receiving tubes with their open ends are placed in diametrically opposite sections of the annular gap between the protective casing and the rotor; the conical plates and spacer washers are made with six holes forming three channels for supplying and three channels for draining the liquid, while the holes in the conical plates are closed, the holes in the spacer washers have through holes through the periphery and are installed in the bag so that in each channel, the closed holes in the spacer washers alternate with the holes with cutouts on the periphery, and adjacent conical plates differ in outer diameter by an amount multiple of the thickness of the spacer washer.

A patent search showed that individual elements of the claimed model are known in the technique of cleaning liquids from contaminants and mechanical impurities (see books: Shkoropad D.E., Novikov O. Centrifuges and separators for chemical industries. M., Chemistry, 1987 g .; Timonin AS Fundamentals of the design and calculation of chemical-technological environmental equipment. Handbook, vol. 2, chapter 37. Kaluga, 2006; Zalmanzon LA. Aerohydrodynamic methods for measuring input parameters of automatic systems., M., Science, 1973). However, the above set of interconnected distinctive features is not found and does not explicitly follow from the level of technology development. In connection with the above, the claimed technical solution is considered to be consistent with the conditions of patentability "novelty."

The essence of the claimed utility model is reflected in the accompanying drawings. A general view of the centrifuge is shown in figure 1. Figure 2 shows a cross section of the rotor, and figure 3 is a longitudinal section thereof. Figure 4 shows a conical plate, and figure 5 is a spacer washer.

On the basis of 1 placed the rotor 2 and the motor 3, connected by a V-belt transmission 4 containing a centrifugal clutch 5. The rotor has an upper 6 and lower 7 seals. A pack of 8 inserts is placed inside the rotor. On top of the rotor is closed by a protective casing 9, on which the rotor rotation indicator 10 is fixed (Fig. 1).

The rotor rotation detector includes a housing 11 with a diaphragm 12 located inside it with the formation of two cavities 13 and 14, respectively connected by tubes 15 and 16 with an air annular gap 17 between the rotating rotor and the stationary protective casing in diametrically opposite sections of this gap. On the housing 11 is placed a microswitch 18, connected by a sleeve 19 to the diaphragm 12. The free ends of the tubes 15 and 16 have each oblique slice 20 facing the rotating rotor (see figure 2).

The rotor contains an outer cylindrical shell 21, lower 22 and upper 23 of the cover and the shaft 24 (see figure 3). A package of inserts is placed on the shaft, consisting of conical plates 25 and 26 (varying in outer diameter) and spacer washers 27 located on the outside of the package and between the plates to form a combination of alternating inter-tray spaces 28 and 29. The shaft 24 is mounted in bushings 30 on bearings 31 and has inlet 32 and outlet 33 channels.

In each conical plate 25 (26) and in each spacer plate 27, six matching holes 34 (35) are arranged uniformly around the circumference (see FIGS. 4 and 5). In addition, in the spacer washers 27, three of these holes, located at 120 degrees, have through cuts 36 at the periphery (Fig. 5).

Holes 34 (35) during assembly of the package form six vertical longitudinal channels, three of which, located after 120 degrees, form channels 37 for supplying fluid; they are connected by three drillings 38 to the main supply channel 32. Three other longitudinal channels, offset from the first by 60 degrees, form channels 39 for draining fluid from the rotor package and are connected by three drillings 40 to the main discharge channel 33. Between the package of 8 inserts and the shell 21 clearance 41 is formed.

Adjacent conical plates 25 (26) installed in the bag are made with different outer diameters D1 or D2 (FIG. 4), differing by a multiple of the thickness S of the spacer plate 27 (FIG. 5). The optimal hydraulic regime of fluid movement in the inter-tray 28 and 29 spaces, with the creation of a zone of flow inhibition near the edge of the smaller plate, is ensured by the condition D1-D2 = (3: 6) S.

Adjacent spacers 27 installed in the bag between the conical plates 25 (26) are rotated relative to each other by 60 degrees so that the cutouts 36 connect each inter-tray space 28 (29) with either the channels 37 or the channels 39. In accordance with this assembly rule, all the inter-tray spaces 28 are the fluid supplying from the channels 37 to the separation zone, and all the inter-tray spaces 29 alternating with them are fluid-withdrawing from the periphery to the channels 39.

A centrifuge for cleaning liquids is as follows.

Previously, the rotor 2 is filled with a working fluid through the union of the lower seal 7. After that, the drive motor 3 is turned on. The centrifugal clutch 5 provides a smooth set of rotor revolutions up to 6500 rpm in about 45 seconds.

When the rotor rotates, the pressure head in the air annular gap 17, perceived by the tube 15, is created directly by the air flow in the wall region of the rotor. As the rotor speed increases, the pressure difference in the tubes 15 and 16 increases and begins to act on the diaphragm 12. After the rotor reaches the working speed, the pressure drop reaches its maximum, and the diaphragm stroke provides the microswitch 18. This signal on the fact of the rotor reaching the working speed includes external feed pump (not shown in the drawings).

In the cleaning process, the fluid through the fitting of the lower seal 7 and the main supply channel 32 enters through the drilling 38 into three channels 37 for supplying fluid. Then, passing through the cutouts 36 in the spacer washers, the liquid is divided into thin layers in the inter-tray spaces 28. Due to centrifugal forces, the liquid is freed from particles whose specific gravity exceeds the specific gravity of the liquid being cleaned. These particles are deposited on the inner surfaces of the conical plates and then transported further along them and through the gap 41 to the inner surface of the cylindrical shell 21. The fluid flow rotates 180 degrees to enter the inter-tray spaces 29, from where it passes through other cutouts 36 in an adjacent spacer washer the longitudinal channels 39 and further through the drillings 40 fall into the main outlet channel 33. Freed from impurities and water due to centrifugal forces and due to the effect of flow inhibition near the plate edge of a smaller diameter tra, purified fluid through the upper seal 6 comes in a container of finished products or in intermediate tank for re-separation. Guaranteed by the design of the package of inserts the passage of the entire fluid flow through the periphery of the conical plates, i.e. through the zone with the maximum value of the separation factor, provides a high degree of purification of the liquid. With an initial liquid contamination of about 15 class according to GOST 17216-01, the centrifuge ensures an output purity no worse than class 5 after about 10 minutes of operation at a flow rate of 100 l / min. The automatic determination of the number and size of contaminant particles was carried out with an GRAN-152 optical analytical instrument equipped with a portable printer for recording the results of particle size analysis.

At a flow rate of 80-100 l / min, the differential pressure in the centrifuge is in the range of 2.5-3.0 kgf / sq.cm. In a specific implementation of the utility model, the filter bag contains 230 conical plates 0.5 mm thick each and 231 spacer washers (each 0.8 mm thick). The inner diameter of the shell 21 was bored to a size of 216 mm, and the technological gap 41 was 6 mm. After assembly, the bag is compressed with a force of 5-8 tons to prevent crevice filtering between the plates.

From the description of the design and operation of the claimed utility model, its following main advantages are visible:

- the design of the package of inserts of the centrifuge rotor provides a guaranteed passage of the entire fluid flow through the periphery of the conical plates, i.e. through the zone of maximum influence of the factor of liquid separation on the centrate and water and particles of inorganic pollution differing in density;

- a constant non-contact control of the fact of rotation of the centrifuge rotor is carried out, which prevents breakthrough of incompletely separated contaminants into the output line of the centrifuge while reducing the rotor speed;

- this centrifuge has the ability to restore performance after washing the package of inserts and the inner surface of the shell during routine maintenance, both with a stationary and a rotating rotor;

- alternating the diameter of adjacent conical plates creates an effect of flow inhibition, which leads to a more than two-fold decrease in the velocity of liquid flowing around the edges of a smaller-diameter plate and an increase in the fraction of separated contaminants.

Information sources:

1. Belyanin P.N. Centrifugal purification of working fluids of aviation systems. M., Mechanical Engineering, 1976.

2. Shkoropad D.E., Novikov O.P. Centrifuges and separators for chemical plants. M., Chemistry, 1987.

3. Timonin A.S. Fundamentals of the design and calculation of chemical-technological environmental equipment. Kaluga. 2006 year

4. Zalmanzon L.A. Aerodynamic methods for measuring the input parameters of automatic systems. M., Science, 1973

5. US patent No. 4071118. class 233/29. publ. 01/31/1978, a centrifugal separator.

6. Copyright certificate of the USSR, No. 418115. class B04B 1/08, 1974 Separator for separating suspensions.

7. Copyright certificate of the USSR, No. 581997, cl. B04B 1/04, 1977. Centrifuge for cleaning liquids.

8. Copyright certificate of the USSR, No. 1132983, cl. B04B 1/08, 1985. Rotor of a centrifugal separator.

9. RF patent No. 2191635, cl. B04B 1/08, 2002 Centrifuge.

10. GOST 16887-82. Separation of liquid heterogeneous systems by filtration and centrifugation methods.

11. GOST 17216-2001. Industrial cleanliness. Classes of purity of liquids.

Claims (1)

A centrifuge for cleaning liquids, containing a rotor with upper and lower seals and with a package of alternating conical plates and spacers placed inside it, equipped with a protective casing, and a drive motor mounted on a common base and connected by a V-belt transmission, characterized in that it is additionally equipped placed on the protective casing of the rotor rotation indicator, consisting of two receiving tubes, a housing with a diaphragm and a microswitch mechanically connected to it, and receiving the tubes with their open ends are placed in diametrically opposite sections of the annular gap between the protective casing and the rotor, the conical plates and spacer washers are made with six holes forming three channels for supplying and three channels for draining the liquid, while the holes in the conical plates are closed and the holes in the spacer washers, they have through-holes through the periphery through one, and the spacer washers are installed in the package so that in each channel the closed holes alternate with the holes with cutouts along the periphery, and adjacent conical plates differ in outer diameter by an amount multiple of the thickness of the spacer washer.