RU2019132307A - METHOD OF RETURN WATER SUPPLY USING COOLER - Google Patents

Claims (1)

The method of circulating water supply using cooling towers, which consists in the fact that several cooling towers are interconnected by hydraulic circuits for the preparation and consumption of water, the cooling towers are connected so that the hydraulic circuits for the preparation and consumption of water function separately, while at least , two tanks for collecting water, which are interconnected by a compensation pipe, ensuring the hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that supplies water cooled in the cooling tower to the consumer, which again flows through the valve through the pipeline to the second a tank from which heated water is supplied by a pump through a filter and a valve through a pipeline to a manifold with nozzles located in the upper part of the cooling tower body, and in the area between the filter and the valve, a filter hydraulic resistance control system is installed, consisting of a pressure gauge and a valve, wherein each of the nozzles contains a body that is hollow, axisymmetric, the axis of which is perpendicular to the axis of the manifold pipe hole, and the shape of the body is made in the form of a body of revolution formed by a second-order curve, for example spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and with on the side of the flow hole of the manifold pipe in the nozzle there is a straightening element made in the form of a ring having a central sleeve with which at least three radially located blades are rigidly connected, connected to the nozzle body, and the body is made with two oppositely located perpendicularly the axis of the nozzle, with ledges through which the nozzle is fixed to the manifold through clamps with locks, while in the lower part of the nozzle body there is a conical throttle hole connected to the mixing chamber, which is located between the throttle hole and the straightening element, and on the inner surface of the mixing chamber they have with helical grooves, the fan cooling tower is made in the form of a housing, a spray device, a tank for collecting liquid and a fan, while the housing consists of two parts - an upper part, including a sprinkler and a droplet separator, between which there is a collector of a spray device with all-piece nozzles and a lower part, in which there is a water-collecting tank for collecting cooled water with a fan installed on it, and the body is made of thin sheet stainless steel, and in the water-collecting tank there is a diffuser, which is a part of the body and is connected to a fan made with a plastic impeller and a multi-speed electric motor , allowing in the process of operation, depending on weather conditions, to change the performance of the cooling tower by changing the air flow rate, and the droplet separator is made with triple corrugation, where the air flow changes the direction of movement three times, and due to this, a significant reduction in droplet nose, and at an air velocity in the flow area of the droplet separator from 4 to 4.5 m / s, the degree of separation of droplet moisture is 99.9%, while the amount of droplet entrainment is 0.1% of the amount of water passing through the cooling tower at the nominal mode , and a decrease in the water flow through the cooling tower reduces the amount of droplet entrainment to 0.05%, while the collector of the sprinkler is located in the upper part of the body and is a system of parallel-connected pipes, on which all-torch nozzles are staggered by means of clamps with locks, and the sprinkler cooling towers are made in the form of a module of layers of polymeric cellular pipes, the pipes are cylindrical, placed in all layers parallel to each other and welded at the ends of the module with each other at the points of contact, while the cavities of each of the pipes and the annular space are filled with hollow polymer balls, and the diameter of the balls 5 ÷ 10% more than the maximum cell size of the pipes, while the cooling tower sprinkler is made are used in the form of a module of layers of polymeric cellular pipes assembled from corrugated sheets, which are welded along the edges of the corrugations, and the structure of the channels is made from the following combinations: straight-meandering, straight-oblique, meandering-oblique, characterized in that the nozzle of the collector located in the upper part of the cooling tower body is made containing a hollow cylindrical body with a throttle washer connected to a union nut to which a liquid flow divider is attached, and the liquid flow divider consists of coaxially arranged perforated conical shells, the space between which is filled with a fine mesh, and the tops of the conical the surfaces of the shells are directed away from the throttle washer, while a cylindrical perforated segment is fixed in the lower part of the divider, fixed on perforated conical shells, while in a cylindrical perforated segment fixed in the lower part of the divider on perforated conical rings a flow swirler, made in the form of a spring, a flow swirler, located in a cylindrical perforated segment, made in the form of a perforated screw, while a sprayer made in the form of a truncated cone surface is attached to the end surface of the union nut, axisymmetrically to the body, is fixed on the end surface of the union nut, and a perforated disk is attached to the larger base, and a pipe for supplying compressed air is fixed on the mesh filter, axisymmetrically to the axis of the nozzle, the cut of which is located at the level of the throat of the Helmholtz resonator located inside the throttle washer with a nozzle, and made in in the form of a toroidal cavity, and at least three Helmholtz resonators are located on the perforated disk attached to the larger base of the surface of the truncated cone of the atomizer, the resonator bushings of which, performing the functions of the throats of the “Helmholtz” resonator, are directed towards o si of the nozzle, perpendicular to it.