RU2020130751A - AIR COOLING UNIT WITH RECYCLING WATER EVAPORATION - Google Patents

Claims (4)

1. Air cooling unit with evaporation of recirculating water, containing a housing on which a centrifugal fan is mounted, a centrifugal pump, an air cooling chamber in which perforated containers with an inert nozzle in the form of porcelain rings are installed on perforated gratings, irrigated with recirculated water by means of spray nozzles, on At the outlet of the air cooling chamber, a layer of porcelain rings is placed on the perforated grid, which serves as a drop catcher, and each of the nozzles is made in the form of a housing with an inlet made in the form of a confuser and a throttle hole coaxial with it, and the swirl chamber is made in the form of a cylindrical glass, the axis which in the plane of the drawing is perpendicular to the axis of the inlet and throttle holes, while the axis of the inlet and throttle holes in the profile plane is located tangentially with respect to the swirl chamber, and the nozzle insert is located coaxially with the swirl chamber, inside which in three calibrated holes are made sequentially located and coaxial to each other and the cylindrical surface of the swirl chamber: conical, cylindrical and shaped in the form of a cylindrical part with a rounding chamfer at the outlet, while the diameter of the cylindrical hole of the nozzle insert is equal to the diameter of the upper base of the truncated cone of the conical hole and the diameter of the cylindrical part shaped hole, the ratio of the diameter d of the cylindrical hole of the nozzle liner of the wide-torch centrifugal nozzle to the diameter d _{1 of} the throttle hole of the nozzle body lies in the optimal range of values: d/d ₁ =1.4÷2.2; the ratio of the outer diameter D _{1 of} the nozzle liner to the diameter D of the lower base of the truncated cone of the conical hole of the liner lies in the optimal range of values: D ₁ /D=1.2÷1.8; the ratio of the length L of the nozzle body to the length L _{1 of} the inlet confuser lies in the optimal range of values: L/L ₁ =2.0÷2.5, or each of the nozzles contains a hollow cylindrical body, consisting of a cylindrical part with an external thread for connection to to the fitting of the distribution pipeline for supplying liquid, and coaxially to the body, in its lower part, a nozzle is fixed, formed by a cylindrical surface, turning into a conical surface, which is closed by an end blind partition with a jet in its center, while the body and nozzle form three, coaxial with each other, internal cylindrical chambers, and in the nozzle, on the side opposite to the liquid supply, an additional row of jets is made, which are formed by mutually perpendicular vertical and horizontal channels intersecting on the conical side surface of the nozzle with the formation of outlet holes, while an acoustic block, made in the form of a spherical Helmholtz resonator coaxially located to the nozzle body axis with resonator inserts located perpendicular to the nozzle axis, while the acoustic unit is fixed on a perforated conical surface rigidly connected to a perforated plate mounted on the cut of the cylindrical sleeve of the acoustic unit. 2. Air cooling unit according to claim 1, characterized in that each spray nozzle for spraying perforated containers with an inert nozzle in the form of porcelain rings is made in the form of a pneumatic nozzle for spraying liquids, containing a hollow body with a nozzle and a central core, the body is made with a channel for air supply and contains a coaxial, rigidly connected to the body, sleeve with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve, the upper cylindrical stage of which is connected by means of a threaded connection to a central cylindrical core having a through internal central hole and installed with an annular clearance relative to the inner surface of the cylindrical bushing, and the annular gap is connected to at least three radial channels made in the two-stage bushing, connecting it with the annular cavity formed by the inner surface of the bushing and the outer surface in of the upper cylindrical stage, wherein the annular cavity is connected to the body channel for supplying air under pressure, while in the upper part the central cylindrical core is coaxially connected to the tube for supplying liquid, the diameter of the internal cavity of which is equal to the diameter of the through internal central hole, and in the lower part of the central cylindrical of the core, a hollow conical swirler is fixed, the conical shell of which is fixed by means of at least three spokes fixed at one end on the conical shell of the swirler, in its upper part, and at the other end in an annular groove made on the inner surface of the central cylindrical core, while a screw thread is made on the outer surface of the hollow conical swirler, while to the diffuser with ejection holes, enclosing a cylindrical core with a hollow conical swirler fixed in its lower part, an atomizer in the form of a cylindrical a rigid shell, on the cut of which, by means of at least three spokes, a disk is fixed with a cone facing the apex towards the hollow conical swirler, and on the side surface of which a screw screw is fixed, the direction of the helix of which is opposite to the direction of the helix of the hollow conical swirler, and the top of the cone lies in the plane of the diffuser cut. 3. The air cooling unit according to claim 2, characterized in that screw spray drums are rotatably attached to the spokes of the atomizer of the pneumatic nozzle, made in the form of a cylindrical shell, the direction of the helical lines of which is opposite to the direction of the helical line of the cone, fixed on the disk by means of spray needles. 4. The air cooling unit according to claim 1, characterized in that the inert nozzle placed in perforated containers placed on perforated gratings irrigated with recirculating water is made of a toroidal shape with an axis of symmetry having a circle in cross section with an axis of symmetry parallel to the axis of symmetry of the toroidal surface, in which non-through recesses are made on one side relative to the axis of symmetry of the circle in the section of the toroidal surface and non-through recesses on the other side of the diametrical section relative to the axis of symmetry, while the recesses have an elongated shape in the section in a direction parallel to the axis of the toroidal section of the nozzle, while the recess on one side of the toroidal surface is located between two adjacent recesses made on the other side of the toroidal surface.