RU63512U1 - CONTROL-VORTEX DEVICE - Google Patents

Abstract

The utility model relates to heat engineering and can be used in the heat power, chemical, petrochemical and food industries as a contact heat exchanger or centrifugal-vortex deaerator. The achieved result of the utility model is the activation of the mixing of rotating media, the reduction of hydraulic resistance during their movement, and the reduction of the noise level. This is ensured by the fact that, according to the utility model, a part of the apparatus body within the annular chamber for supplying coolant is made in the form of vertical pins arranged around the circumference of the shell with the same pitch and inserted into at least one row of identical flat segments having two profiled sections on each two adjacent free pins side walls and nozzle assemblies of the required configuration between adjacent segments of the same row. Moreover, in adjacent rows, the segments should be located with a shift of half a step. 1 n.p. 2-silt

Description

The utility model relates to heat engineering and can be used in the heat power, chemical, petrochemical and food industries as a contact heat exchanger or centrifugal-vortex deaerator.

Known accepted as the closest analogue is a contact vortex apparatus intended for the interaction of two media with different densities, comprising a vertical cylindrical body with tangential nozzles in the upper part for supplying a denser medium, an annular chamber surrounding the housing for supplying a less dense medium, and a system of uniformly distributed over the housing wall within the nozzle chamber to form a vortex motion of a less dense medium [1].

The most preferred for the organization of heat transfer between heating and heated media is the use of tangential nozzles. According to [1], “beveled” nozzles close to them are used, oriented in the direction of rotation of the medium flow. In this case, the coolant injected into the heated medium can not only not provide hydraulic resistance to the rotating flow, but also give it additional kinetic energy, and its jets can provide a longer path inside the heated flow layer, which helps to intensify heat transfer. Such nozzles are usually made either directly in the housing, or in the form of cylindrical inserts included inside this housing. Moreover, for the formation of jets in a given direction, the nozzle channel must have a length close to the diameter of the inlet. The implementation of the nozzle with such a channel length in the thickness of the body is difficult to manufacture, leads to an unjustified increase in the thickness of the body and complicates the processing of the surface of the channel of the nozzle. Nozzles, which are inserts inside the body, create hydraulic resistance for the swirling flow and leave a wall layer that is not miscible with the heating medium. Also made in the casing

“Beveled” nozzles have sharp edges at the inlets, which creates additional hydraulic resistance for the flow entering them. If steam or gas is used as a less dense mixed medium, then at sufficiently high rates of their outflow from the nozzles, acoustic vibrations are generated in the latter, creating a strong noise that negatively affects the operating personnel.

The achieved result of the utility model is the activation of the mixing of rotating media, the reduction of hydraulic resistance during their movement, and the reduction of noise level.

This result is ensured by the fact that in the contact-vortex apparatus designed for the interaction of two media with different densities and containing a vertical cylindrical body with tangential nozzles in the upper part for supplying a denser medium, an annular chamber surrounding the housing for supplying a less dense medium and a system of uniformly distributed along the wall of the housing within the chamber of the nozzles to form a vortex motion of a less dense medium, according to a utility model, a portion of the housing within the specified the annular chamber is arranged in the form of its circumference at the same pitch and the vertical pins planted for every two adjacent free pin in at least one row of identical planar segments having profiled side walls and forming a desired configuration of the nozzle assembly between adjacent segments of one row. Moreover, in adjacent rows, the segments should be located with a shift of half a step.

Profiled segments with ease of assembly make it possible to realize nozzles in the form of curved channels that interface the radial inlet of each nozzle with an outlet that is oriented in a direction close to the tangential direction of rotation of the flow supplied through the nozzles. As a result, the flow stream of a less dense medium (coolant), when passing through such a nozzle, deviates smoothly, without turbulent turbulence, in a direction close to tangential. This is especially important when supplying as a less dense medium steam or gas, which

at sufficiently high speeds, the proposed design does not generate acoustic vibrations and thereby does not create a noticeable noise effect. In addition, when assembling the nozzle system of the apparatus from profiled segments, it becomes possible to get as close as possible to the tangential direction of motion of the jets flowing from the nozzles, which ensures intensification of the mixing of media in their entire volume. It also intensifies the processes of heat transfer and deaeration of the heated medium.

The technical solution described, despite the rather complicated geometry of the nozzles, allows them to be manufactured in a relatively simple way. The whole structure as a whole is collapsible, which increases its maintainability. If necessary, you can reduce or increase the number of rows of nozzles, changing their total area, and thereby rebuild the thermal performance of the installation.

Figure 1 shows the contact-vortex apparatus (deaerator) according to the utility model in longitudinal section; figure 2 is a view along arrow A on the part of the housing assembled from flat segments (with the sealing sleeve removed).

Contact-vortex apparatus for the interaction of two media with different densities according to the utility model contains a vertical cylindrical body 1 (Fig. 1) with tangential nozzles 2 in the upper part for supplying a denser medium (for example, water), an annular chamber 3 for supplying as a coolant of a less dense medium (for example, steam or condensate) with a radial pipe 4 and a system of nozzles 5 evenly distributed over the wall of the housing 1 within the chamber 3 (Figs. 1 and 2). Nozzles 5 serve for heat transfer, mixing of flows and intensification of the vortex motion of a denser flow. Part of the housing 1 within the specified annular chamber 3 is made in the form of vertical pins 6 located around the circumference of the housing 1 with the same step S, and mounted on each two adjacent free pins 6 of several (in this case nine) rows of identical flat segments 7 having profiled side walls and nozzle assemblies 5 of the required configuration between adjacent segments 7 of the same row. In adjacent rows, segments 7 are located with

a half-step shift S / 2. The sleeve 8 is used to seal the joint between the solid and assembled from the segments 7 parts of the housing 1. The pan 9, made in the form of a round disk, is used to receive heated water and supply it along the periphery through the slots 10 between the pallet 9 and the lower end of the housing 1 into the evaporation compartment 11 having tangential nozzles 12 for discharging heated deaerated water. On the axis of the housing 1 is installed connected to the evaporation compartment 11 evaporation pipe 13.

Contact-vortex apparatus according to the utility model operates as follows. The initial liquid is supplied through the tangential nozzles 2 to the upper part of the cylindrical body 1. In the absence of back pressure at the outlet of the apparatus, the rotating liquid cylindrical layer is pressed by centrifugal force to the inner surface of the cylindrical body 1 and flows down it under the action of gravity. In the presence of back pressure, the rotating fluid flow will not be annular, but continuous, occupying the entire cross section of the cylinder. Through a pipe 4 radially located relative to the apparatus axis, a medium with a lower density than the density rotating in the housing of the liquid is supplied to the chamber 3. Through a system of nozzles 5 oriented in the direction of rotation of the liquid, the heating medium (for example, water vapor or condensate), from the annular chamber 3, breaking into trickles, enters the housing 1, where it mixes with the heated liquid (for example, water). Under the action of the Archimedean force, a less dense heating medium is pushed to the axis of rotation, providing contact heat transfer in the entire volume of the cylindrical layer of the heated medium. In the embodiment of the deaerator (apparatus without backpressure), the inner part of the housing 1, where the liquid layer (water) is heated by a heating medium (steam or condensate), is separated from the evaporation compartment 11. This separation is carried out by means of a water trap created by a cylindrical layer of water flowing downward with a delay its round pan 9. Water, continuing its rotation, is sprayed along the directions tangential to the rotation path through the slot 10, which is formed by the pan 9 with the lower open end of the cylindrical body 1. Next, water jets fall on a cylindrical surface of a larger radius, which is

the inner surface of the evaporation compartment 11. The heated water, continuing its rotation without the arrival of a heating medium, flows to the outlet tangential nozzles 12. In this case, the vapor is discharged into the inner space of the cylindrical body not filled with water 1. A central vapor pipe 13 is used to remove the vapor.

This unit can also be used as a heat exchanger without performing the deaeration function. In this case, the evaporation pipe 13 is not required. In the presence of back pressure in the housing 1, there is a rotation not of a liquid cylindrical layer, but of a continuous liquid cylinder and the apparatus can only perform the function of a heat exchanger.

Figure 1 shows the contact-vortex apparatus (deaerator) according to the utility model in longitudinal section; figure 2 is a view along arrow A on the part of the housing assembled from flat segments.

Contact-vortex apparatus for the interaction of two media with different densities according to the utility model contains a vertical cylindrical body 1 (Fig. 1) with tangential nozzles 2 in the upper part for supplying a denser medium (for example, water), an annular chamber 3 for supplying less dense medium (for example, steam or condensate) with a radial pipe 4 and a system of nozzles 5 evenly distributed over the wall of the housing 1 within the chamber 3 (Figs. 1 and 2). Nozzles are used for heat transfer, mixing flows and enhancing the vortex motion of a denser flow. Part of the casing 1 within the specified annular chamber 3 is made in the form of vertical pins 6 located around the circumference of the casing 1 with the same step S, and nine rows of identical flat segments 7 having profiled side walls and forming assembled on each two adjacent free pins 6 nozzles 5 of the desired configuration between adjacent segments 7 of one row. In adjacent rows, segments 7 are located with a shift of one step S / 2. The sleeve 8 is used to seal the joint between the solid and assembled from the segments 7 parts of the housing 1. The pan 9, made in the form of a round disk, serves to receive heated water and feed it along the periphery through the slots 10 between the pallet 9 and the lower end of the housing 1 in

an evaporation compartment 11 having tangential nozzles 12 for discharging heated deaerated water. On the axis of the housing 1 is installed connected to the evaporation compartment 11 evaporation pipe 13.

Contact-vortex apparatus according to the utility model operates as follows. The initial liquid is supplied through the tangential nozzles 2 to the upper part of the cylindrical body 1. In the absence of back pressure at the outlet of the apparatus, the rotating liquid cylindrical layer is pressed by centrifugal force to the inner surface of the cylindrical body 1 and flows down it under the action of gravity. In the presence of back pressure, the rotating fluid flow will not be annular, but continuous, occupying the entire cross section of the cylinder. Through a pipe 4 radially located relative to the apparatus axis, a medium with a lower density than the density rotating in the housing of the liquid is supplied to the chamber 3. Through a system of nozzles 5 oriented in the direction of rotation of the liquid, the heating medium (for example, water vapor or condensate), from the annular chamber 3, breaking into trickles, enters the housing 1, where it mixes with the heated liquid (for example, water). Under the action of the Archimedean force, a less dense heating medium is pushed to the axis of rotation, providing contact heat transfer in the entire volume of the cylindrical layer of the heated medium. In the embodiment of the deaerator (apparatus without backpressure), the inner part of the housing 1, where the liquid layer (water) is heated by a heating medium (steam or condensate), the inner cavity of the housing 1 is separated from the evaporation compartment 11 due to the hydraulic lock created by the flowing down cylindrical layer of water with a delay its pan 9. Water, continuing its rotation, is sprayed along the directions tangential to the rotation path through the slot 10, which is formed by the pan 9 with the lower open end of the cylindrical body 1. Next, the water jets fall on and a cylindrical surface of a larger radius, which is the inner surface of the evaporation compartment 11. Heated water, continuing its rotation without the arrival of a heating medium, flows to the outlet tangential nozzles 12. In this case, the vapor enters the inner, not filled with water

the space of the cylindrical body 1. To remove the vapor, a central evaporation pipe 13 is used.

This unit can also be used as a heat exchanger without performing the deaeration function. In this case, the evaporation pipe 13 is not required. In the presence of back pressure in the housing 1, there is a rotation not of a liquid cylindrical layer, but of a continuous liquid cylinder, and the apparatus can only perform the function of a heat exchanger.

Information sources:

1. Patent RU No. 2178131, F28C 3/06, 2000.

Claims (2)

1. Contact-vortex apparatus designed for the interaction of two media with different densities, comprising a vertical cylindrical housing with tangential nozzles in the upper part for supplying a denser medium, an annular chamber surrounding the housing for supplying a less dense medium, and a system uniformly distributed over the housing wall within chamber nozzles for the formation of vortex motion of a less dense medium, characterized in that a part of the housing within the specified annular chamber is made in the form located of its circumference with the same pitch and the vertical pins planted for every two adjacent free pin in at least one row of identical planar segments having profiled side walls and forming a desired configuration of the nozzle assembly between adjacent segments of one row. 2. Contact-vortex apparatus according to claim 1, characterized in that in adjacent rows the segments are located with a shift of half a step.