RU2653460C1 - Heat recovery unit with boiling bed of inert head - Google Patents

Abstract

FIELD: cooling.

SUBSTANCE: invention relates to apparatus for waste air heat recovery and for cooling circulation water, as well as for adiabatic cooling and air humidifying in ventilation and air conditioning systems. Heat recovery unit with boiling bed comprises a body, a separator, a water distributor, injectors, a movable inert head, a pallet and a support grid, wherein guide apparatus and float valve are additionally arranged in the body, and a vibrator is mounted on the support grid, and a movable inert head is made in the form of a cylindrical ring, on side inner surface of which partitions in the form of washers with holes perpendicular to the ring axis are fixed, which axes are asymmetric to the ring axis, or a movable inert head is made in the form of a block inscribed in a circle, consisting of seven interconnected side edges of hexagonal parallelepipeds without an upper and a lower base, or a movable inert head is made in the form of interconnected helical spirals, inscribed in a spherical surface with a center lying on the axis of the connection of the spirals, or a movable inert head is made in the form of at least twelve connected in a block of three-bladed propellers, which projection onto the drawing plane is inscribed in a circle with a center coinciding with the center of one of them.

EFFECT: increased efficiency and reliability of the dust collection process by increasing the liquid spraying rate of injectors.

1 cl, 10 dwg

Description

The invention relates to apparatus for utilizing the heat of the removed air and cooling the circulating water.

The closest technical solution to the claimed object is a heat recovery unit according to the patent of the Russian Federation No. 2612485, F24F 5/00 (prototype) containing a metal casing, a separator, a water distributor, nozzles, a movable nozzle made of hollow plastic balls, a tray and a support grid.

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped spray surface of the liquid.

EFFECT: increased efficiency and reliability of the dust collection process by increasing the degree of liquid atomization by nozzles.

This is achieved by the fact that in a heat recovery unit with a fluidized bed of an inert nozzle containing a metal housing, a separator, a water distributor, nozzles, a movable nozzle made of hollow plastic balls, a tray and a support grid, moreover, a guide apparatus and a float valve are additionally placed in the housing, and a support vibrator is installed, each of the nozzles consists of a housing with an inlet, a cover, a gasket between the housing and the cover, a spring located between the cover and the swirl made in in the form of an inverted cylindrical cup mounted relative to the housing with an annular gap, moreover, at least two rows of throttle openings are made in the swirl, and at least two tangential throttle openings are evenly spaced along the annular wall of the swirl, and in the lower part of the housing a nozzle insert with a calibrated conical hole coaxial with the cylindrical surface of the swirler and a taper inverse taper is installed in the form of a conical washer onicheskoy insert washers.

In FIG. 1 shows a General view of the proposed installation, in FIG. 2 is a general view of the nozzle, in FIG. 3-10 - embodiments of the shape of the movable inert nozzle 4.

The heat recovery unit with a fluidized bed of an inert nozzle consists of a separator 1, a water distributor 2, nozzles 3, a movable nozzle 4 of hollow plastic balls (forming the so-called "fluidized bed"), a tray 5, a support grid 6, a metal casing 7, a guiding apparatus 8 , float valve 9, with which a constant level of water is maintained in the pan, and a filter 10 located in the lower part of the housing and holding various suspended solids in the water. To intensify the process of heat and mass transfer, a vibrator (not shown) is installed on the support grid 6.

The nozzle irrigation system of a two-stage contact heat exchanger 1 includes a nozzle (Fig. 2), which contains a housing 11 with a screw 17 coaxially located in the lower part of the housing and a nozzle 12 located in the upper part of the housing with a cylindrical fluid inlet 13 connected to a diffuser 14, an axisymmetric housing 11 and a nozzle 12. For a tight connection of the housing 11 with the fitting 12, a sealing gasket 15 is provided. The screw 17 is pressed into the housing with the formation of a conical chamber 16 located above the screw 17, oosno diffuser 14, which is connected in series with it. The screw 17 is made continuous, the outer surface of the screw 17 being two serially connected surfaces, one of which is at least a single-threading helical groove 18 with right or left thread and is located inside the housing 11, and the second surface 20 is made smooth in the form of a body of revolution axisymmetrically connected to the spray disk 21 by means of a rod 22 located perpendicular to the axis of the housing, and protrudes beyond the end surface of the lower part of the housing, moreover, as a line, This surface can be either a straight line or an nth-order curved line, for example, spherical, elliptical, parabolic, etc. (not shown). In this case, the screw 17 can be fixed in the housing by means of screws 19. The nozzle screw 17 is made of solid materials: tungsten carbide, ruby, sapphire.

The surface of the spray disk 21, protruding beyond the end surface of the lower part of the housing 11, is bent toward the lower part of the housing and has radial cutouts (not shown) on the peripheral part, alternating with the solid part of the surface of the spray disk 21.

A heat recovery unit with a fluidized bed of an inert nozzle operates as follows.

The balls of the movable nozzle 4, under the influence of the upward flow of air and the water entering it, move, colliding with each other, and thereby significantly intensify the processes of heat and mass transfer between the sprayed water and the air entering the apparatus. The intensification of the process of heat and mass transfer contributes to the installed on the support grid 6 vibrator.

The swirl nozzle 3 operates as follows.

The fluid is supplied through a cylindrical hole 13 to the diffuser 14, and from it to the conical chamber 16, from which it flows under pressure into the screw external cavity of the screw 17. A rotating fluid flow in the external screw cavity of the screw forms a vortex movement, with additional crushing of liquid drops due to turbulization of the outlet stream, and a finely dispersed rotating stream leaves the nozzle with a wide rotating torch of the sprayed liquid (solution) and encounters the surface of the spray disk 21, otorrhea at the peripheral portion bent toward the lower housing portion, provided with radial cutouts alternating with a continuous part of the surface of the spray plate 21, thus increasing the surface of the liquid while spraying additional fragmentation of liquid droplets.

With the nominal productivity of the apparatus and the water pressure in front of the nozzle 98 kPa, the nozzle 4 is stationary at a mass air velocity of up to 2.7 ... 2.9 kg / (m ² ⋅ s), and with an increase in this speed to 3 ... 3.1 kg / (m ² ⋅с) the movement of balls 4 begins, the process of heat and mass transfer is significantly intensified, but the aerodynamic resistance of the apparatus also increases. Therefore, mass air velocities higher than 4.1 ... 4.3 kg / (m ² ⋅ s) should not be taken, since the balls exit the working zone, pressing against the separator 1, and the aerodynamic drag of the apparatus sharply increases, which is: 0 , 12 kPa at a mass velocity of 2 kg / (m ² ⋅ s), 0.2 kPa - at 3 kg / (m ² ⋅ s), and 0.35 kPa - at 4 kg / (m ² ⋅ s). The dimensions of the apparatus are 0.65 × 0.65 × 1.9 m, the living section area in the working area is 0.42 m ² .

Fluidized bed apparatuses are widely used in circulating water supply systems (for cooling recirculating water) in the baking industry and in public catering establishments, as well as their effective use in ventilation systems of those enterprises where, according to technological requirements, it is necessary to maintain high relative humidity throughout the year .

It is possible to perform the form of a movable inert nozzle (Fig. 3) in the form of a cylindrical ring on the lateral, inner and outer surfaces, which are screwed (not shown) in opposite directions. It is possible to form a movable inert nozzle (Fig. 4) in the form of a ball, on the surface of which non-through holes of a hemispherical shape (not shown) are made. It is possible to form a movable inert nozzle (Fig. 5) in the form of a ring, on the outer surface of which a helical surface is made like a plate auger. It is possible to form a movable inert nozzle (Fig. 6) in the form of at least a three-blade propeller.

It is possible to make a movable inert nozzle 4 (Fig. 7) in the form of a cylindrical ring, on the lateral, inner surface of which there are fixed partitions in the form of washers perpendicular to the axis of the ring with holes whose axes are asymmetric to the axis of the ring.

It is possible to perform a movable inert nozzle 4 (Fig. 8) in the form of a block inscribed in a circle, consisting of seven hexagonal parallelepipeds connected together by side faces without upper and lower bases.

It is possible to perform a mobile inert nozzle 4 (Fig. 9) in the form of interconnected helical spirals that fit into a spherical surface with a center lying on the axis of the connection of the spirals.

It is possible to perform a movable inert nozzle 4 (Fig. 10) in the form of at least twelve three-bladed propellers connected to a block, the projection of which onto the plane of the drawing fits into a circle with a center coinciding with the center of one of them.

Claims (1)

A heat exchanger with a fluidized bed of an inert nozzle containing a metal body, a separator, a water distributor, nozzles, a movable inert nozzle, a tray and a support grid, moreover, a guide apparatus and a float valve are additionally placed in the housing, and a vibrator is installed on the support grid, and each of the nozzles consists of a housing with a screw coaxially located in the lower part of the housing, and a fitting located in the upper part of the housing with a cylindrical hole for supplying fluid connected to a diffuser, axisymmetric to to the housing and the fitting, the screw is pressed into the housing with the formation of a conical chamber located above the screw, coaxial to the diffuser, and connected to it in series, moreover, the screw is solid, and the external surface of the screw is two serially connected surfaces, one of which is at least one-way screw groove with right or left thread, and is located inside the housing, and the second surface is made smooth in the form of a body of revolution, axisymmetrically connected to the spray disk, distributed perpendicular to the axis of the casing, and protrudes beyond the end surface of the lower part of the casing, moreover, the line forming this surface can be either a straight line or an nth-order curved line, and the surface of the spray disk protruding beyond the end surface of the lower part of the casing is made bent towards the lower part of the housing and has on the peripheral part radial cuts alternating with the solid part of the surface of the spray disk, characterized in that the movable inert nozzle is made in the form of qi a cylindrical ring, on the side, on the inner surface of which partitions are fixed in the form of washers perpendicular to the axis of the ring with holes, the axes of which are asymmetric to the axis of the ring, or a movable inert nozzle is made in the form of a block inscribed in a circle, consisting of seven hexagonal parallelepipeds connected to each other by side faces without an upper and the lower base, or a movable inert nozzle is made in the form of interconnected helical spirals that fit into a spherical surface with a center lying on the c axis unity spirals, or inert movable nozzle is in the form of at least twelve connected in tri-block propellers whose projection on the plane of the drawing fits into a circle with the center coinciding with the center of one of them.

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