RU204736U1 - Centrifugal liquid purification separator with annular channels - Google Patents

Abstract

The utility model relates to the field of separation of liquids, namely to devices intended for cleaning aviation fuel from water and suspended heavy impurities due to centrifugal forces (hereinafter referred to as cleaning). EFFECT: increased efficiency of liquid purification from impurities and heavy fractions. A deeper cleaning of the fuel takes place while maintaining the dimensions of the device due to an increase in the residence time in it of the laminar flow of the cleaned liquid, which is under the action of centrifugal forces. The separator contains a housing with inlet and outlet openings, a nozzle for removing heavy fractions. A rotor is placed inside the housing with the possibility of rotation, which is a central pipe rigidly coaxially fixed to each other and an outer shell provided with holes. A gap is formed between the outer shell and the body for the removal of heavy fractions. Between the central tube and the outer casing of the rotor, a stack of concentric tubes is placed, forming successively communicating annular channels.

Description

The utility model relates to the field of separation of liquids, namely to devices intended for cleaning aviation fuel from water and suspended heavy impurities due to centrifugal forces (hereinafter referred to as cleaning).

The prototype of the utility model is a centrifugal liquid purification separator containing a body with inlet openings, an outlet flange and a branch pipe. In the inner cylindrical cavity of the body there is a rotor with the possibility of rotation, which is rigidly, coaxially fixed to each other, inner and outer pipes, between which a passage channel is formed, while the outer pipe is equipped with holes, and a sealed gap is formed between the outer pipe and the body for removing impurities ... Due to centrifugal forces, aviation fuel is purified by separating the mixture into light and heavy fractions, with the removal of the latter (Patent RU 2484877, IPC B01D 17/038, 2013).

The disadvantage of the known separator is the low efficiency of purification of the initial mixture, due to the short duration of the flow of the purified mixture in the flow path of the device, as well as the low service life due to the rapid failure of the bearing assemblies.

The task of the utility model is to improve the centrifugal liquid purification separator, which makes it possible to increase its operational characteristics.

The technical result is to increase the efficiency of cleaning the liquid from impurities and heavy fractions.

The technical result is achieved by the fact that the centrifugal liquid purification separator contains a housing with inlet and outlet openings, a nozzle for removing heavy fractions. Inside the housing, a rotor is placed with the possibility of rotation, which is a central pipe rigidly coaxially fixed to each other and an outer shell provided with holes. A gap is formed between the outer shell and the body for the removal of heavy fractions. It differs in that between the central pipe and the outer shell of the rotor, a package of concentric pipes is placed, which forms successively communicating annular channels.

The above essence of a utility model is a set of essential features of a utility model that ensure the achievement of the claimed technical result.

The utility model, in comparison with the prototype, provides such a residence time of the liquid to be purified in a laminar flow state with the simultaneous action of centrifugal forces on it, which makes it possible to achieve a deeper degree of purification of the initial mixture from impurities and heavy fractions.

When a fluid flows in an annular channel, a laminar flow arises and stabilizes at Reynolds numbers:

where: υ - fluid flow rate;

v - indicator of the kinematic viscosity of the liquid;

d _eq - the equivalent diameter of the channel, which for the annular channel is equal to the difference between the outer and inner diameters of the channel d _eq = Dd.

Since the kinematic viscosity index (v) is determined by the type of liquid to be purified, and the liquid flow rate (υ) and the equivalent channel diameter (d _eq ) are taken based on the required performance, it is possible to achieve a deeper fuel purification by increasing the length of the annular channel, which will allow to increase the residence time of the laminar fluid flow under the action of centrifugal forces in it.

In the description of the prototype it is indicated that the optimal ratio of the lengths of the outer and inner pipes (L) to the outer diameter of the inner pipe (d), which should not exceed values of the order: L / d <6 ... 8, was experimentally established. This ratio is optimal, since exceeding it leads to increased vibrations and rapid failure of bearing assemblies.

But tests of prototype samples showed that the length of the channel can be increased without exceeding a certain, specified above, limit (L / d <6 ... 8).

The technical result achieved in the claimed utility model consists in a deeper purification of the fuel while maintaining the dimensions of the device by increasing the residence time in it of the laminar flow of the purified liquid under the action of centrifugal forces.

Due to the labyrinth of annular channels, the limit of the ratio of the lengths of the outer and inner pipes (L) to the outer diameter of the inner pipe (d), which for an analogue should not exceed values of the order of: L / d <6 ... 8, was eliminated.

In special cases, it is permissible to carry out a utility model as follows.

The body is expediently made in the form of a cylinder with an inlet flange and a cover, between which a rotor is mounted on bearings. In this case, the rotor is equipped with blades on the side of the cover and is closed at two ends by discs. The inlet is connected to the inner cavity of the central pipe, which is provided with through windows on the side of the cover, and is closed at this end with a shank. In this case, the concentric tube package is composed of three tubes. In this case, the shell, the blades and one of the disks are preferably made as a single welded part, in which the blades form an impeller that acts as a blower for the movement of the fluid flow. In this case, the impeller blades will connect the outer cylindrical tube of the shell with its disk, fixed on the central tube. One rotor bearing is secured in the housing and the other in a removable housing cover. The disc connected to the blades is desirably connected to the central pipe by a splined connection with a retaining ring. In this case, the other disk can be provided with a groove for the outer shell, placed in the groove of the central pipe and pressed against the outer shell with a nut.

The stack of concentric pipes is preferably made to ensure a sequential movement of the fluid flow from the first channel adjacent to the central tube to the last one adjacent to the channel shell, while the direction of flow in adjacent annular channels is opposite.

On the inner surface of all pipes of the package at the end of each annular channel in the direction of flow, it is advisable to make annular grooves with tubes installed in them, connecting each groove with the last channel adjacent to the shell.

The annular channels of the separator can be divided by radial partitions into sections, the section of which is close to rectangular in shape.

The inlet and outlet openings are desirably located at opposite ends of the housing.

A centrifugal liquid purification separator is shown in Fig. 1, which shows its longitudinal section. FIG. 2 shows a cross-section of a stack of pipes in the area of section A-A of FIG. 1, FIG. 3 is an enlarged longitudinal section of the separator in the area of the blades; FIG. 4 is an enlarged longitudinal section of the separator at the other end of the package of pipes, section B-B of FIG. 2, FIG. 5 is an enlarged longitudinal section of the separator at this end of the package of pipes, section D-D of FIG. 2, FIG. 6 is a cross-section of the central tube in the region of the through windows.

The centrifugal liquid purification separator (Fig. 1) consists of a housing 1 made in the form of a cylinder with a flange and a cover 5, between which a rotor is mounted on bearings 6 (not indicated). The rotor is a central pipe 7, on which a package 9 is installed, consisting of three concentric pipes 10, an outer shell 8, blades 11 and two discs 12, 13. The basic element of the rotor is a central pipe 7, on which the package 9 is installed (Fig. 2 ), consisting of three concentric pipes 10. The package 9 is located in the annular gap between the outer surface 71 of the central pipe and the inner surface 81 of the shell. From one end of the shell 8 by means of blades 11 is connected to the disk 12 (Fig. 3). Shell 8, blades 11 and disc 12 are one monolithic (welded) part, in which the blades form an impeller. To transmit torque from the central tube 7, the disc 12 and the central tube are splines (not shown). The assembly of the rotor into a single unit is ensured, on the one hand, by the splined connection of the disc 12 with the central pipe 7 (not shown) and the retaining ring 16, limiting the longitudinal movement of the disc 12 along the pipe 7 towards the cover 5, and on the other hand, by the disc 13, which rests on the end of the shell 8 (Fig. 4) and presses the package 9 to the disk 12. The disk 13 is provided with a groove for the outer shell 8 and is located in the groove of the central pipe 7. This ensures the concentricity of the central pipe and the cylindrical perforated shell. The force for fixing the disk 13 in the pressed state is provided by the nut 14, locked by the bend washer 15. The pipes 10 are assembled into a package 9 by means of screws 17. The concentricity of the installation of pipes in the package is provided by smooth bushings 18. In the radial direction, the pipes of the package are pressed from the inside by the nuts screwed onto the screws 17 19, acting as internal spacer sleeves. In the assembled rotor, a labyrinth of annular channels is formed between the pipe 7, the pipes 10 of the package 9 and the shell 8. The movement of fluid flows in adjacent channels will be opposite (shown by arrows). In the course of fluid movement at the end of each annular channel on the outer surface of the pipe forming it there are annular grooves 20 (Figs. 3, 4, 5). Tubes 21, 22, 23 connect each of the bores 20 to the outer annular channel 24 formed by the outer tube of the package 9 and the inner surface of the shell 8. The tubes serve to drain into the channel 24 heavy fractions separated in each of the channels located below. Along the entire length of the tubular shell 8, small holes 25 are made in it, through which the separated solid particles and heavy fractions enter the annular gap 26 (the gap between the stationary body 1 and the rotating shell 8). The holes 25 are made evenly along the entire length of the shell. Choke 4 is used to remove separated fractions from the separator.

To eliminate liquid leaks from zones with different compositions and pressures, there are sealing collars 27 installed between the stationary and rotating parts of the separator.

On the side opposite to the inlet of the central tube 7, a shank 28 is rigidly fixed, designed to drive the rotor into rotation. In the immediate vicinity of the attachment point of the shank in the pipe 7, through holes 29, evenly distributed over the diameter, are made (Figs. 1, 6), connecting the cavity of the central pipe 7 with the adjacent (inlet) annular rotor channel.

In order to increase the length of the sections of the stabilized laminar flow and the total flow rate of the liquid flowing through the device, its annular channels are divided into sections by radial partitions. The section of the sections is close to rectangular in shape when the thickness of the channel of the annular sector, bounded by two adjacent baffles, is equal to the distance between these baffles.

An inlet 2 with a flange in the housing 1 is used to supply the original (unpurified) mixture to the device, and an outlet 3 located on the opposite side of the housing in the form of a pipe with a flange serves to drain the cleaned fuel. The inlet can be a limited area with entrance windows.

Centrifugal liquid purification separator works as follows. The inlet 2 and outlet 3 holes are connected through the flanges to the corresponding pipelines, after which the rotor is brought into rotation.

When the rotor of the impeller blade 11 rotates, performing the function of a pump, a pressure drop is created, due to which the liquid, entering through the inlet 2 of the housing into the device, moves along the central pipe 7. At the end of the pipe 7, through the windows 29 in it, the initial mixture enters into a labyrinth formed by a package of pipes 10 located in the annular space between the central pipe 7 and the shell 8. In the first annular channel, the direction of flow becomes opposite to its direction in the tube 7. In the second channel, it becomes opposite to its direction in the first annular channel, and so .d. In the figures shown, the number of pipes 10 in the package 9 is three, but in general it can have any integer value.

Due to the small difference between the outer and inner diameters of the annular channels and the relatively long length of the labyrinth channels, a large section of a stabilized laminar flow regime is formed in them (the laminar flow is stabilized in a section 15 to 50 D-d differences from the entry point into the channel).

Under the action of centrifugal forces, the mixture is separated into fractions by density, and from the moment it enters the channel, the concentration of heavy fractions occurs at the outer generatrix of each annular channel. At the end of each annular channel, on the inner surface of the pipe forming it (which is the outer wall of the channel), annular grooves 20 are made, in which the heavy fractions separated during the flow in this channel are collected. These fractions by means of branch pipes 21 (in the first channel, Fig. 4), 22 (in the second channel, Fig. 3) and 23 (in the third channel, Fig. 5) are continuously withdrawn into the outer annular channel 24 into the zone immediately adjacent to the inner surface of the shell 8 of the rotor.

In the fourth channel, which is the most distant from the center of rotation, the effect of centrifugal forces on the separated heavy fractions is maximal, and they, pressed by centrifugal forces against the inner wall of the perforated shell 8, through small holes 25 located along its length are diverted into the annular gap 26 between the shell and the body 1 During the operation of the device, the channel 26 is continuously filled with the separated fractions and their continuous withdrawal from the device through the nozzle 4. The purified liquid (fuel), passing through the blades 11 and the diffuser, is also continuously withdrawn from the device through the outlet nozzle 3.

Claims (7)

1. A centrifugal liquid purification separator containing a housing with inlet and outlet openings, a nozzle for removing heavy fractions; inside the housing, a rotor is placed with the possibility of rotation, which is a central pipe rigidly coaxially fixed to each other and an external shell provided with holes, while the rotor is equipped with an impeller, a gap is formed between the outer shell and the body for the removal of heavy fractions, characterized in that a pack of concentric pipes is placed between the central tube and the outer shell of the rotor, forming successively communicating annular channels; on the inner surface of all tubes of the pack at the end of each annular channel in the direction of flow annular grooves with tubes installed in them, connecting each groove with the last channel adjacent to the shell. 2. A separator according to claim 1, characterized in that the body is made in the form of a cylinder with an inlet flange and a cover, between which a rotor is mounted on bearings, while the rotor is equipped with blades forming the said impeller from the cover side and is closed at two ends by disks, the inlet the hole is connected to the inner cavity of the central pipe, which is provided with through windows on the side of the cover and is closed at this end with a shank, while the package of concentric pipes is made up of three pipes. 3. A separator according to claim 2, characterized in that the shell, blades and one of the discs are one welded part. 4. A separator according to claim 2 or 3, characterized in that the disk connected to the blades is connected to the central pipe by a splined connection with a retaining ring, and the other disk is provided with a groove for the outer shell, is placed in the groove of the central pipe and is pressed against the outer shell by a nut. 5. The separator according to any one of paragraphs. 1-4, characterized in that the stack of concentric pipes is made to ensure a consistent movement of the fluid flow from the first channel adjacent to the central pipe to the last adjacent to the channel shell, while the direction of flow in adjacent annular channels is opposite. 6. A separator according to claim 1, characterized in that its annular channels are divided by radial partitions into sections, the section of which is close to rectangular in shape. 7. The separator according to any one of paragraphs. 1-6, characterized in that the inlet and outlet openings are located at opposite ends of the housing.

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