RU181747U1 - FLOW COOLER IRRIGATOR UNIT - Google Patents

Abstract

The utility model relates to designs of countercurrent cooling tower sprinklers and can be used in evaporative cooling of process water in recycled water supply systems, as well as to find application in almost all industries: petroleum gas, chemical and heat power engineering. The countercurrent cooling tower sprinkler block contains irrigation elements made in the form of hollow pipes with a rectangular groove in the rectangular section located on their outer surface in increments of 0.5D, where D is the diameter of the pipe into which the elastic brush frame harness is flush without gaps with a height of 10 nylon thread bundles mm, evenly spaced in a row after 2 mm, while the ends of the elastic brush frame tow are fixed at the beginning and end of the pipe with locking bolts that also fasten the ends of the pipes mounted on the plugs 0.05L high, where L is the length of the pipe, while the plugs are staggered at the crosshairs of cells measuring 70 × 70 mm of the upper and lower rectangular gratings - the lower ones under the upper ones, respectively, and the gratings are connected at the corners using four corners located inside the sprinkler, forming a cube of 700 × 700 × 700 mm. The technical result is an increase in heat and mass transfer in the processes of evaporative cooling. 5 ill.

Description

The utility model relates to the design of cooling tower sprinklers and can be used in evaporative cooling of process water in recycled water supply systems, as well as find application in almost all industries: oil, gas, chemical, and in the power system.

A countercurrent cooling tower sprinkler is known that contains tiered vertical irrigation elements made in the form of four blade screws, the height of which is equal to the pitch, rigidly interconnected into packets made with rotation in a vertical plane relative to each other and with an offset in the horizontal plane (RF patent No. 2350877).

The disadvantage of this sprinkler is the low efficiency of heat and mass transfer.

The technical problem solved by the proposed device is to increase the efficiency of heat and mass transfer in the processes of evaporative cooling by increasing the surface area of the interface between liquid and gaseous media.

The essence of the utility model consists in the fact that in the irrigation unit of the counterflow cooling tower, including vertical irrigation elements made of high pressure polyethylene in the form of vane augers, irrigation elements are made in the form of hollow pipes with a rectangular groove on the outer surface with a pitch of 0, 5D, where D is the diameter of the pipe into which the elastic brush frame tourniquet is laid flush with no gaps with a height of 10 mm nylon filament bundles uniformly placed in a row after 2 mm, at m the ends of the elastic brush frame tow are fixed at the beginning and end of the pipe with locking bolts that also fasten the ends of the pipes mounted on plugs 0.05L high, where L is the length of the pipe, while the plugs are staggered at the crosshairs of cells measuring 70 × 70 mm the upper and lower rectangular lattices are the lower ones under the upper ones, respectively, and the lattices at the corners are interconnected using four corners located inside the sprinkler block, forming a cube of 700 × 700 × 700 mm.

In FIG. 1 shows a sprinkler unit of a counterflow cooling tower; in FIG. 2 - end view of the block; in FIG. 3 is a longitudinal section of a pipe with a helical groove; in FIG. 4 - elastic brush frame; in FIG. 5 is a transverse section of irrigation pipes.

The cooling tower sprinkler block contains vertically arranged pipes 1 made of thermoplastic material with an elastic brush frame 2. The elastic brush frame 2 consists of bundles of nylon threads 3 with a diameter of 0.4 ... 0.5 mm and a height of 10 mm, fixed to the bundle 4 at one end, and evenly placed in one row at equal intervals of 2 mm. The bundle 4 is attached at the beginning and end of the pipe and flush without gaps is inserted into the screw grooves of rectangular cross section 5, cut along the length of the pipes to a depth equal to the thickness of the bundle 4, in increments of 0.5D, where D is the diameter of the pipe. Pipes are mounted on plugs 6, staggered on the upper and lower detachable rectangular grilles 7, on the inside of the block, one opposite the other, respectively, until they touch the grilles, and are fixed with locking bolts 8, which simultaneously fix the tourniquet with a brush frame. The lattices 7 are interconnected at four corners by vertical corners 9 placed inside the cube. The optimal length of the plugs 6, providing the necessary rigidity of the block, is 0.05 L, where L is the length of the pipe. The cross section of pipes with an elastic brush frame is 64 mm, and without a frame - 44 mm. The size of the grill is 700 × 700 mm. The plugs are located at the crosshairs of the grill inside the block in a checkerboard pattern into which they are flush-mounted and fastened with pipe pins.

Pipes, grids, plugs and fastening corners can be made, for example, of low-pressure polyethylene or of polyvinyl chloride.

The cooling tower sprinkler blocks are assembled by installing pipes 1 between split gratings 7, fitting them onto plugs 6 and fastening them with corners 9. As a result, a cube is formed, the height, width and length of which are 700 mm.

The device operates as follows. When cooling water is supplied to the tower sprinklers, a sprayed droplet of water forms on the outer surface of the pipes 1, as well as on an elastic brush frame, on each thread of a bunch of nylon threads 3, a film of flowing water, 50-55 μm thick, interacting with the air coming from below through free space in the sprinkler (between tubes with an elastic brush frame), as a result, an emulsification flow regime is created in which media (liquid and gaseous) are inverted, i.e. constantly changing roles - then one, then the other becomes solid or dispersed. This media inversion promotes the intensification of heat and mass transfer and increases the efficiency of water cooling. The staggered arrangement of plugs with pipes mounted on them increases the turbulization of liquid and air media, which also increases the efficiency of heat and mass transfer.

The technical result of the use of the invention lies in the fact that the film flow of fluid along the structural elements of the sprinkler due to the creation of an extensive surface of the contacting flows of liquid and gas, rupture of the liquid film in the volume of the sprinkler, turbulence of the contact flows, increases heat and mass transfer by 16-20% in the processes evaporative cooling with a decrease in the mass of the design of the sprinkler and the tower as a whole.

Claims (1)

An irrigation unit of a counterflow cooling tower, including vertical irrigation elements made of high pressure polyethylene in the form of vane screws, characterized in that the irrigation elements are made in the form of hollow pipes with a rectangular groove on the outer surface of them with a pitch of 0.5D, where D is the diameter of the pipe into which the elastic brush frame harness is flush-mounted without gaps with a height of 10 mm nylon filament bundles uniformly placed in a row after 2 mm, while the ends of the bundle are elastic The brush frames are fixed at the beginning and end of the pipe with locking bolts that also fasten the ends of the pipes mounted on plugs with a height of 0.05L, where L is the length of the pipe, while the plugs are staggered at the crosshairs of the cells 70 × 70 mm in size upper and lower rectangular lattices - the lower ones under the upper ones, respectively, and the lattices at the corners are interconnected by means of four corners located inside the sprinkler block, forming a cube of 700 × 700 × 700 mm.

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