RU123407U1 - CENTRIFUGAL-VORTEX DEAERATOR - Google Patents

Abstract

1. Centrifugal vortex deaerator, containing a cylindrical body with a centrifugal swirler, a feed water supply pipe, a deaerated water outlet pipe and a steam-air mixture outlet pipe, characterized in that it is equipped with a drive with an output shaft, while the centrifugal swirler of the deaerator is made rigidly composed of on the cylindrical body of the deaerator of the fixed part, made in the form of an inverted glass with a flange, and a drive disk, while the drive is rigidly fixed on the outer surface of the bottom of the glass, in the bottom of the glass there is a hole for the passage of the output shaft of the drive, at the end of which the drive disk is rigidly fixed fixed on its surface from the side of the flange of the glass at least two concentric rings, and on the surface of the flange of the glass from the side of the drive disk there is at least one annular row of rigidly fixed guide vanes, and on the surface of each of the concentric rings of the drive the claim has an annular row of rigidly fixed swirl blades, while the feed water supply pipe is located in the wall of the centrifugal swirler glass, concentric rings with the corresponding annular row of swirl blades of the drive disk are located relative to each other so that a number of guide vanes of the glass flange can be freely placed between them, and the drive disk is installed with the possibility of sequential passage of the initial water from the cavity of the glass of the centrifugal swirler to the inner wall of the deaerator body. 2. Centrifugal vortex deaerator according to claim 1,

Description

The utility model relates to a power system and can be used to remove gases from feedwater in heating and hot water systems.

A device for deaeration of water is known, comprising a cylindrical degasser with a capacity for accumulating deaerated water, a source pipe for supplying water with a sprinkler, a steam outlet pipe with a vacuum pump and a pipe for draining water from the storage tank, while the sprinkler is made in the form of a multi-nozzle head located in the lower part degasser housing, the device is equipped with a reflector with an impeller installed in the bearing assemblies in the upper part of the housing with the possibility of rotation, a collector located coaxial to the housing, and a perforated helical plane mounted in the manifold. The device can be equipped with flow swirls mounted on the inner surface of the degasser and collector body in the reflector zone and made of plates located along a helical line or at an angle of 10-15 ° to the plane of the body cross section. (RF patent No. 2076768, IPC 6В01D 19/00, СOF 1/20, 1997 (analogue)).

Known vortex deaerator, including a cylindrical body with end caps, one of which has an axial hole and / or pipe, while on the side surface of the body next to the cover having an axial hole, there is an outlet (holes) and / or pipe near the opposite cover , an inlet pipe is tangentially connected to the side surface of the housing, and between them, closer to the outlet, there is a partition containing at least one hole made near the side of the cylinder physical housing. The vortex deaerator can be equipped with a flow swirl made in the form of a snail. (RF patent for utility model No. 76017, IPC 6C02F 1/20, 2008 (analogue)).

Known jet vortex deaerator, containing a vertically placed housing with a side nozzle for supplying heated water, a swirl with spiral channels having a variable cross-section, tapering from entrance to exit, mounted coaxially in the upper part of the housing, and a cowling, mounted coaxially in its lower part, between the lower edge of the swirl and the upper edge of the fairing, a cylindrical rotation chamber with a profiled inner surface is formed. (RF patent No. 2392230, IPC 6C02F 1/20, 2010 (analogue)).

The closest in technical essence to the claimed one is a vortex deaerator containing a cylindrical body with a centrifugal swirler and a cowl located in it, while the body has a source water supply nozzle, a deaerated water outlet nozzle and a water-air mixture outlet nozzle connecting the cavity between the swirler and the cowling with the cowling , and a regulatory body included in the water-air mixture pipeline. (Summary of description of application No. 2008120170 for the grant of a patent of the Russian Federation, IPC 6C02F 1/20, 2009 (prototype)).

A disadvantage of the known solution is that the water enters the deaerator with an insufficiently large supply of kinetic energy to provide a more complete separation of the gases dissolved in the source water without additional heating of the source water.

When creating a useful model, the problem of both expanding the arsenal of water deaeration devices and increasing the efficiency of deaerating the source water without heating it was solved.

The technical result consists in providing the possibility of multiple spasmodic changes in the speed of movement of the source water.

The specified technical result is achieved due to the fact that the centrifugal vortex deaerator contains a cylindrical body with a centrifugal swirl, a source pipe for supplying water, a pipe for draining the deaerated water and a pipe for removing the vapor-air mixture, according to a utility model, it is equipped with a drive with an output shaft, while the centrifugal swirl the deaerator is made up of a fixed part rigidly fixed to the cylindrical body of the deaerator, made in the form of an inverted glass with a flange, and a drive of the drive, while the drive is rigidly fixed on the outer surface of the bottom of the glass, in the bottom of the glass there is a hole for passage of the output shaft of the drive, at the end of which the drive disk is rigidly fixed with at least two concentric rings rigidly fixed to its surface from the side of the glass flange, on the surface of the flange of the glass from the side of the drive disk there is at least one annular row of rigidly fixed guide vanes, and on the surface of each of the concentric rings of the drive disk an annular row of rigidly fixed swirl blades is being drawn, while the source water supply pipe is placed in the wall of the centrifugal swirl cup, concentric rings with the corresponding annular row of swirl blades of the drive disk are arranged relative to each other, allowing a number of guide blades of the cup flange to be freely placed between them and the drive the disk is installed with the possibility of sequential passage of the source water from the cavity of the glass of the centrifugal swirler to the inner their walls deaerator housing.

Moreover, according to the utility model, the deaerated water outlet pipe is located in the bottom of the deaerator, and the steam-air outlet pipe is located inside the deaerator body and brought out through its bottom, while the intake part of the steam-air mixture outlet pipe is located in the upper part of the deaerator body.

Moreover, according to the utility model, the drive is made in the form of an electric motor with a reducer, on the output shaft of which the drive disk is rigidly fixed.

Moreover, according to the utility model, each of the concentric rings is made protruding above the surface of the drive disk to a height greater than the gap between the surface of the drive disk and the lower end of the guide vanes of the cup flange.

Moreover, according to the utility model, each of the swirling blades is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation with the possibility of rapidly increasing the speed of movement of the source water entering them.

Moreover, according to the utility model, each of the guide vanes of the flange of the glass is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation with the possibility of quick stopping of water jets coming from the swirling blades of the drive disk of the centrifugal swirler.

A distinctive feature of the claimed device is that the centrifugal vortex deaerator is equipped with a drive with an output shaft, while the centrifugal swirl is made up of a fixed part rigidly fixed to the cylindrical body of the deaerator, made in the form of an inverted glass with a flange on the surface of which there is at least at least one annular row of rigidly fixed guide vanes overlapping water jets and a drive disk rigidly fixed to the output shaft of the drive with sculpt jet swirl vanes in concentric rings, with the actuating drive is configured to sequential passage of source water from the cavity cup centrifugal swirl to the inner walls of the deaerator housing only through the interaction as a swirl of the drive disc vanes, and the guide fixed flange nozzle vanes.

In addition, the distinguishing features of the inventive centrifugal-vortex deaerator are also the structural features of the arrangement of the guide vanes of the flange of the glass of the centrifugal swirler and the swirl vanes of its drive disk, which made it possible to form a series of serially connected cavities concentrically placed one after another from the cavity of the glass to the inner walls of the deaerator body , the source water supply pipe is located in the wall of the glass of the centrifugal swirler, which in turn could provide supplying feed water directly to the first annular row of swirl vanes of the drive disk.

As a result, the indicated technical result was achieved: the possibility of multiple stepwise changes in the speed of movement of the source water, which in turn leads to an increase in the efficiency of deaeration of the source water without additional heating.

The utility model is illustrated by a description of a specific example of its implementation and the accompanying drawings, where:

figure 1 shows a centrifugal vortex deaerator (General view);

figure 2 - section aa figure 1 (view of the guide vanes of the flange of the glass from the side of the drive disk (conditionally swirling blades of the drive disk are not shown);

figure 3 - section BB figure 1 (view of the swirling blades of the drive disk from the side of the flange of the glass (conventionally, the guide blades of the flange of the glass are not shown).

The centrifugal-vortex deaerator contains a cylindrical body 1 with a centrifugal swirler 2, a supply pipe for the source water 3, a pipe for the removal of deaerated water 4 and a pipe for the discharge of a water-carrying mixture of stuffy mixture 5 (Fig. 1).

The centrifugal swirl 2 is made up of a fixed part, for example, by means of bolted joints of a traditional design, on the cylindrical body 1 of the vortex deaerator of the fixed part, made in the form of an inverted glass 6 with a flange 7, and a drive disk 8.

The centrifugal-vortex deaerator is equipped with a drive 9, which can be made in the form of a traditional design, for example, a typical electric motor with or without a gearbox, as shown in our example, with an output shaft, which is the output shaft 10 of the drive 9.

The drive 9 is rigidly fixed to the outer surface 11 of the bottom 12 of the glass 6 of the fixed part of the centrifugal swirler 2.

For the passage of the output shaft 10 of the drive 9 in the bottom 12 of the glass 6, the hole 13 is made.

At the end of the output shaft 10 of the drive 9 is rigidly fixed, for example, by means of a standard threaded connection, the drive disk 8 of the centrifugal swirler 2.

On the flange 7 of the glass 6 of the fixed part of the centrifugal swirl 2 from the side of its drive disk 8, there is at least one annular row of rigidly fixed guide vanes 14. In our example, as shown in Fig. 1, there are two annular rows of rigidly fixed guide rails blades 14: small row 15 and large row 16 (FIG. 3).

Each of the guide vanes 14 (Fig. 2) is made in the form, for example, of a plate placed at an angle to the radius drawn to it from the axis of rotation, so that they completely block the stream of water coming from the swirl blades 17 of the drive disk 8 of the centrifugal swirler 2, i.e. each of the guide vanes 14 of the flange 7 of the glass 6 is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation, with the possibility of a quick stop of the water jets coming from the swirling blades 17 of the drive disk 8 of the centrifugal swirler 2.

The blades 14 can be made in the form of, for example, metal plates and rigidly fixed to the flange 7, for example, by welding.

On the drive disk 8 of the centrifugal swirler 2 from the side of the flange 7 of the Cup 6 there are at least two concentric rings that can be made, for example, are turned at the same time in the manufacture of the drive disk 8. Concentric rings are made protruding above the surface of the drive disk 8 to a height a large gap between the surface of the drive disk 8 and the lower end of the guide vanes 14 of the flange 7 of the glass 6 of the swirler 2. On the surface of each of the concentric rings is rigidly fixed, for example, by welding vortex blades 17.

In our example, as shown in Fig. 1 and Fig. 3, there are three concentric rings, and therefore, three annular rows of rigidly fixed on them, for example, by welding, swirl blades 17: small row 18, middle row 19 and large row 20 (FIG. 3).

Each of the swirl vanes 17, as well as the guide vanes 14, is made in the form of, for example, a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation, so that they disperse the water entering them from the supply pipe 3 source water and / or from the guide vanes 14 of the flange 7 of the centrifugal swirler 2, i.e. each of the swirl blades 17 is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation, with the possibility of a quick increase in the speed of rotation of the source water entering them.

The blades 17 can be made in the form of, for example, metal plates and rigidly fixed to the corresponding concentric ring, for example, by welding.

It should be noted that a large row 16 of guide vanes 14 of the flange 7 of the cup 6 is separated from the small row 15 of the guide vanes 14 of the flange 7 at a distance sufficient for the swirl vanes 17 of the respective row of the drive disk 8 to pass freely. As shown in FIG. a small row 15 of guide vanes 14 of the flange 7 and a large row 16 of guide vanes 14 of the flange 7 is the middle row 19 of the swirl blades 17 of the drive disk 8 of the centrifugal swirler 2.

The middle row 19 of swirl vanes 17 of the drive disk 8 is spaced from the small row 18 of swirl vanes 17 of the drive disk 8 at a distance sufficient to freely accommodate the guide vanes 14 of the flange 7 of the corresponding row between them, i.e. as shown in figure 1, between the small row 18 of swirl vanes 17 of the drive disk 8 and the middle row 19 of the swirl vanes 17 of the drive disk 8 there is a small row 15 of the guide vanes 14 of the flange 7, between the middle row 19 of the swirl vanes 17 of the drive disk 8 and a large row 20 swirl vanes 17 of the drive disk 8 posted a large row 16 of guide vanes 14 of the flange 7.

Thus, we can say that the annular rows 15 and 16 of the guide vanes 14 of the flange 7 are located relative to each other with the possibility of free passage between them of the corresponding row of swirl vanes 17 of the drive disk 8, and concentric rings 18, 19 and 20 with the corresponding annular row of swirls the blades 17 of the drive disk 8 are located relative to each other with the possibility of free placement between them of the corresponding row of guide vanes 14 of the flange 7 of the glass 6.

In addition, to ensure the possibility of sequential passage of the source water from the cavity of the glass 6 of the centrifugal swirler 2 to the inner walls of the housing 1 of the deaerator, the drive disk 8 is mounted so in relation to the flange 7 of the glass 6 that between the lower ends 21 of the guide vanes 14 of the flange 7 and the bottom 22 of the grooves there is a gap between the concentric rings 18, 19 and 20 with the annular rows of swirl vanes 17 of the drive disk 8, and since the height of each of the guide vanes 14 and the total height of the concentric ring with each of the swirls of the vanes 17 are the same, the same gap exists between the upper ends 23 of the swirl vanes 17 of the drive disk 8 and the bottom 24 of the grooves between the annular rows 15 and 16 of the guide vanes 14 of the flange 7, while the lower ends of the guide vanes 14 of the flange 7 are located below the surface level of the corresponding concentric rings 18, 19 or 20 to prevent the breakthrough of deaerated feed water over the surface of the drive disk 8, bypassing the annular rows of guide vanes 14.

Thus, we can say that the drive disk 8 is installed with the possibility of sequential passage of the source water from the cavity of the glass 6 of the centrifugal swirler 2 to the inner walls 25 of the housing 1 of the vortex deaerator only by interacting with swirl vanes 17 and with guide vanes.

The pipe outlet of the deaerated water 4, having a traditional design, made, for example, in the form of a pipe segment, for example, metal with a flange, is fixed in the bottom 26 of the housing 1 of the vortex deaerator.

The steam-air mixture discharge pipe 5, made in the form of a pipe segment, is placed inside the deaerator body 1 and brought out through the bottom 26 into which it, for example, is welded, while the intake-air mixture 5 discharge pipe 27 is located in the upper part of the vortex deaerator body 1 .

Centrifugal vortex deaerator of water works as follows.

Turn on the drive motor 9. The drive disk 8, rigidly mounted on the end of the output shaft 10, is untwisted. The source water entering through the source water supply pipe 3 is captured by a small row 18 of the swirling blades 17 that are in motion and accelerates to a speed depending on the radius of the small row 18, the rotational speed of the electric motor and the profile of the blades 17. Significant kinetic energy is transmitted to the water. After swirling blades 19, high-speed jets of source water fall on the stationary guide vanes 14 of the small annular row 15, where they break up and sharply reduce their speed, experiencing significant cavitation phenomena and overloads, as a result of which the vapor-gas fraction is separated and separated from water. The stopped jets of water flow down under the action of gravity and fall on the bottom 22 of the corresponding groove between the concentric rings 18, 19 or 20 with the annular rows of swirl vanes 17 of the drive disk 8. Due to centrifugal force, the source water rises along the annular groove above the level of the corresponding concentric ring 18 and is captured by rotating swirl blades 19, where it accelerates to an even higher speed, because the radius of the concentric ring 19 is greater than that of the ring 18. With even greater kinetic energy, the water hits a fixed row of guide vanes 14 of the row 16. In this case, the remaining gases are released from the water. Low-speed jets of water flow to the bottom 22 of the annular groove between the annular rows of swirling blades 17 rows 19 and 20, where it begins to unwind again. The untwisted water is captured by an annular row of 20 swirl blades 17 and, having accelerated to a maximum speed determined by the rotational speed of the electric motor, the radius of the annular row of swirl blades of the ring row 20 and the profile of the blades 17, falls on the inner inclined part of the housing 1, where the foam and the remaining bubbles are finally separated. gases from water. Flowing in a spiral along the inner wall 25 of the housing 1, deaerated water reduces the speed and leaves the deaerator along the pipe 4. The released gases and steam are removed through the pipe branch of the vapor-air mixture 5.

Thus, it is possible to repeatedly jump in the speed of movement of the source water, which in turn leads to a significant increase in the rate of release of dissolved gases without heating the water by supplying significant mechanical energy to the source water immediately before the moment of cavitation-vortex exposure and repeatedly repeating this effect if necessary deep deaeration of water.

Claims (6)

1. Centrifugal-vortex deaerator containing a cylindrical body with a centrifugal swirl, a supply pipe for the source water, a pipe for removing the deaerated water and a pipe for removing the steam-air mixture, characterized in that it is provided with a drive with an output shaft, while the centrifugal swirl deaerator is made up of rigidly on the cylindrical body of the deaerator of the fixed part, made in the form of an inverted glass with a flange, and a drive disk, while the drive is rigidly fixed to the outer surface on the cup, in the bottom of the cup, a hole is made for the output drive shaft to pass through, at the end of which the drive disc is rigidly fixed with at least two concentric rings rigidly fixed to its surface from the side of the cup flange, and at least there is at least one concentric ring on the surface of the cup flange from the side of the cup at least one annular row of rigidly fixed guide vanes, and on the surface of each of the concentric rings of the drive disk there is an annular row of rigidly fixed swirl vanes, while the source water supply nozzle is located in the wall of the centrifugal swirl cup, the concentric rings with the corresponding annular row of swirl blades of the drive disc are arranged relative to each other, allowing a number of guide blades of the flange of the cup to be freely positioned between them, and the drive disc is installed so that the source water can pass sequentially from the cavity of the glass of the centrifugal swirler to the inner wall of the body of the deaerator. 2. The centrifugal-vortex deaerator according to claim 1, characterized in that the outlet pipe for the deaerated water is located in the bottom of the deaerator, and the outlet pipe for the steam-air mixture is placed inside the body of the deaerator and out through its bottom, while the intake part of the outlet pipe for the steam-air mixture is located in the upper part of the deaerator body. 3. The centrifugal-vortex deaerator according to claim 1, characterized in that the drive is made in the form of an electric motor, on the output shaft of which the drive disk is rigidly fixed. 4. The centrifugal-vortex deaerator according to claim 1, characterized in that each of the concentric rings is made protruding above the surface of the drive disk to a height greater than the gap between the surface of the drive disk and the lower end of the guide vanes of the cup flange. 5. The centrifugal-vortex deaerator according to claim 1, characterized in that each of the swirl vanes is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation, with the possibility of a quick increase in the speed of rotation of them jets of source water. 6. The centrifugal-vortex deaerator according to claim 1, characterized in that each of the guide vanes of the flange of the glass is made in the form of a flat or curved plate placed at an angle to the radius drawn to it from the axis of rotation, with the possibility of quick stopping of water jets, coming from the swirling blades of the drive disk of the centrifugal swirl.