RU33636U1 - Cooling tower - Google Patents

Description

The proposed technical solution relates to heat engineering, in particular to evaporative coolers - cooling towers, and can be used in thermal and nuclear power plants, as well as in other industrial facilities that require cooling of water or other liquids.

Known fan cooling tower, comprising a housing, enclosed by a casing with the formation of an air outlet channel, an air exhaust pipe installed in the bottom of the housing, equipped with a drainage tray and a louvre grill, an exhaust pipe with a fan, an air distributor with nozzles and air inlets located in the housing cover, in which the cooling system is additionally equipped with air ducts with shut-off valves and a shell located around the side wall of the housing with an annular gap (AS USSR No. 1702144 IPC F28 С 1/00 publ. 1991).

The disadvantage of the proposed cooling tower is an inefficient liquid cooling system, due to the presence of a large amount of liquid in a small space, which in turn makes it possible to let in large air flows and use powerful fan systems.

A cooling tower is also known, comprising an exhaust tower with air inlet windows made in a ring in its lower part, an irrigator with a water distribution system located in the tower above the windows, and water-jet ejectors connected to a water distribution manifold, and ejectors are installed in the central zone of the cooling tower, limited in diameter, equal to 0.2 - 0.25 of the diameter of the sprinkler, the outlet ends face the sprinkler, and the water-distributing collector is located inside the tower. (RF patent No. 2099662, IPC F28 C 1/00 publ. 1997)

The disadvantage of this cooling tower is the inefficiency of cooling caused by the large aerodynamic drag due to the placement of irrigation elements in the mine, but it is impossible to abandon this system, since the irrigation is the device on which heat transfer occurs.

The closest technical solution (prototype) is a cooling tower, comprising a casing with air inlet windows at the periphery in its lower part, and placed in groups on the water distribution manifold located in the window openings, water-jet nozzles mounted at an angle to each other symmetrically relative to the vertical axis of the cooling tower with offset

2003105613

Cooling tower

2 O 03 105613

IPC F28 S 1/00

From the window plane to the center of the cooling tower, the nozzles are mounted on platforms with the possibility of rotation around the horizontal axis by an angle that ensures the height of the intersection point of the liquid torches. Each platform is a rotary housing with movable flanges connected to the water distribution system. On the upper flange of each movable platform, groups of water-jet nozzles are placed ( Patent of the Republic of Belarus No. 3450 IPC F28 C 1/00 publ. 2000)

The disadvantage of the prototype is the implementation of the pipelines of the water distribution system in the form of a stepped pyramid, in which the perimeters for each lower row are reduced relative to the upper. This leads to a decrease in the number of nozzles in each lower level in relation to the higher one, especially in multi-faceted cooling towers, which reduces the performance of the cooling tower, and the connection each rotary platform to the collector through separate rotary flanges significantly complicates the design by increasing the number of -operation of flanges

The objective of the invention is to increase the productivity of the tower by simplifying the water distribution system and simplifying its design, as well as reducing the cost of maintenance and repair of the tower

The problem is solved due to the fact that the known tower contains a housing with air inlets at the periphery in its lower part and water-jet nozzles movably mounted on the collectors in the window opening at an angle opposite each other symmetrically with respect to the vertical axis of the tower at an angle that ensures the intersection height of the jets liquid torches According to the proposed technical solution, the collectors are made rotary and equipped with blocks of water-jet nozzles fixed to them, and the collectors are installed ak inside and outside the housing of the cooling tower are mounted on parallel horizontal rows levels equidistant from the vertical axis of the tower, the height dependence limits the highest and lowest points of intersection of the jets of fluid from the torches limit values nozzles angles to the respective levels determined by the formula

HI - H2 (bj - b2) (tg tti - tg a2) where

Нз - the height of the lowest intersection points of the torch jets from the level of the horizontal axes of the collectors, where the torch jets are symmetrical to the vertical axis of the tower;

bi is the distance from the horizontal axis of the nozzle to the vertical axis of the tower for the nozzles inside the tower;

) 2 - the distance from the horizontal axis of the nozzle to the vertical axis of the tower for nozzles outside the tower;

ttj - tt2 are the limits of the nozzle tilt angles from the corresponding levels.

In addition, the blocks of water-jet nozzles are made in the form of a circle with one central nozzle and from two to eight around it. Blocks of water-jet nozzles can be placed on the collectors, at least in two rows and offset by 0.4 - 0.6 meters from the window plane both inside and outside the cooling tower. Blocks with nozzles are installed on collectors in an amount of 2 to 10 units. The cross section of the tower body can be made in the form of a rectangle, a regular polygon, for example, a hexagon, or in the form of a circle.

Thus, according to the proposed technical solution, the nozzles are located in one vertical plane parallel to the vertical wall of the tower body, and the water distribution system is like a ladder with the same parallel rungs, which allows the internal volume of the tower to be freer. This provides better cooling conditions and thereby increase the performance of the tower, and also improves the conditions for maintenance and repair of the latter.

In FIG. Figure 1 shows a general view of a cooling tower with the placement of collectors with central water-jet nozzles inside the cooling tower in two rows (upper and lower) and intersecting jets of symmetrical fluid flares.

In FIG. Figure 2 shows a general view of a cooling tower with the placement of collectors with central water-jet nozzles outside the cooling tower in two rows (upper and lower) and intersecting jets of symmetrical fluid flares.

In FIG. Figure 3 shows the projections of the fluid torches from the central water-jet nozzles of the upper and lower rows, respectively, to the right and left of the vertical axis of the tower. Section AA in FIG. 1

In FIG. Figure 5 shows the intersection of the jets of liquid torches from the central water-jet nozzles located outside the cooling tower. Section BB in figure 2.

In FIG. 6 shows the intersection of torch jets from central water-jet nozzles located inside, for example, the hexagonal body of the cooling tower.

In FIG. 7 shows the intersection of the jets of liquid torches from the central water-jet nozzles located outside, for example, the hexagonal body of the cooling tower.

On Fig shows a block of water-jet nozzles made in the form of a circle with one central nozzle and, for example, six water-jet nozzles around it.

The cooling tower contains a housing 1 in the form of a vertical duct with air inlet windows 2, made on the periphery in its lower part. In the opening of the windows 2, collectors 3 are installed, which are connected to the water distribution system 4. The collectors 3 are located both inside and outside the tower body. Blocks 5 with water-jet nozzles 6 are fixed on collectors 3. The central symmetric nozzles of block 5 are mounted towards each other at an angle to their level. The collector 3 with blocks 5 of water-jet nozzles 6 is mounted with the possibility of rotation around the horizontal axis of the collector at an angle that provides the height of the intersection of the jets of liquid torches 7 in the form of cones. The cooling tower contains a drainage basin 8.

The jets of symmetrical fluid torches 7 flow out from the central water-jet nozzles 6 in the form of cones and intersect in the vertical plane of the ellipse (Fig. 3).

The jets of symmetrical torches 7 of the liquid flow out from the central water-jet nozzles 6 installed inside the cooling tower in the form of cones and intersect in the horizontal plane of the ellipse (Fig. 4 and 6)

The jets of symmetrical 7 fluid torches flow from the central water-jet nozzles 6 mounted outside the cooling tower in the form of cones and intersect in the horizontal plane of the ellipse, (FIGS. 5 and 7).

The axis of the cones of the torches 7, intersect with the vertical axis of the tower at point B (Fig. 1, 2 and 3). In Figs. 1 and 2, the intersection of these axes forms an isosceles triangle ABC with the base AC. The BD axis divides the triangle ABC into two

equal rectangular triangles ABD and DBC. AD bi (Fig. 1) for central water-jet nozzles 6 inside the tower and AD b2 (Fig. 2) for central water-jet nozzles 6 outside the tower.

The jets of the torch 7 of the liquid flowing from a single water-jet nozzle 6 (Figs. 1 and 2) intersect the vertical axis of the tower at the highest point BI and lowest point B2, with this B D HI B2D H2

The height limits HI - H2 are dependent on the limits of the angles a. - a and the limits of the bases bi - b2 of right triangles ABi D and ABj D and is expressed by the proposed mathematical formula

Hi - H2 (bi - ba) (tg oti - tg a2)

The proposed formula is valid for all formed rectangular triangles of the upper and lower rows (Fig. 1 and 2), as well as all formed rectangular triangles in the sequence from the overlying row to the underlying. The recommended distance between the rows should be at least 0.5 m. The cooling tower works as follows. Cooled water is supplied to the housing through the water distribution system 4, blocks 5 and water-jet nozzles 6 installed on the collectors 3 and water jets emerging from the water-jet nozzles 6 form torches 7 in the form of cones whose axes intersect with the vertical axis of the cooling tower. Collectors 3 can be installed both inside and outside the tower, which provides better cooling tower. Placing the collectors in 3 horizontal rows at parallel levels provides more free internal volume of the tower, which simplifies the design of the water distribution system and better conditions for maintenance and repair of the tower. Since blocks 5 with water-jet nozzles 6 are mounted on the collectors 3 motionlessly, the nozzles are rotated by the required angle due to the rotation of the collector around its axis. Moreover, the dependence of the height limits of the highest and lowest points of intersection of the torch jets 7 on the limits of the values of the angles of inclination of the water-jet nozzles 6 to the corresponding levels is determined by the proposed formula: HI - H2 (bi - b2) (tg cu - tg 012), which allows you to organize the practically required torch height, regardless of the size of the tower, while ensuring high cooling efficiency.

the nozzles are placed in one row (to facilitate the calculation) and are offset 0.4 m from the flashing plane of the window, bi will be 3.6 m for water-jet nozzles located inside the cooling tower. The limits of the angle of inclination of the nozzles to the level of the horizontal axes of the collectors are from 15 to 80 °. At an angle of 30 °, the deviation of the torch jets from the axis of the torch cone is plus or minus 15 °. In this case, the torch jets intersect at the upper point of BI at an angle of 45 ° and at the lower point of B2 at an angle of 15 °, where the height HI will be 1.8 m. (bi x tg30 °), aFk will be 1 m ((bi

x tg 15 °). The HI and HI values are adjusted by tilting the nozzle to the required angle. Substituting the nozzle inclination angle (30 °) into the proposed formula, the distance bi (3.6), we obtain the height of the intersection of the torch jets at the upper BI lower 82 point. Similarly, we obtain the indicated values of the intersection of torch jets for angles, for example, 57 ° and 65 °. Torches 7, in the form of fine droplets, when meeting at a height, form a water dust with a developed surface of droplets when they collide, which fall into the drainage basin 8. When water is supplied through blocks 5 of the water-jet nozzles 6, the latter carry air upward from the air ducts 2 . At the same time, hot water heats this air and convection forces begin to act on it. Air rushes up and meets with water dust falling into the catchment basin 8. When air flows and falling water dust meet, active heat and mass transfer occurs. Water-jet nozzles 6 form a region with reduced pressure in the opening of the air duct windows 2. An air stream rushes into these windows 2, as a result of which forced circulation of air masses without additional energy consumption is organized. In addition, the installation of blocks 5 of water-jet nozzles 6 on a manifold 3 in an amount of from 2 to 10 units provides a significant increase in the cooling tower productivity and heating of the air supplied through windows 2 at the initial stage, additionally providing convection draft in the housing 1. The possibility of turning blocks of 5 water-jet nozzles 6 together with the collector 3 at a certain angle allows you to adjust the direction of the torches 7 of the cooled liquid for each specific cooling tower, taking into account the outside temperature, the initial rate ture cooled fluid force and wind direction and other parameters.

liquids and increasing the cooling tower performance, while lowering operating costs and simplifying the design, increasing its reliability and maintainability. In addition, the proposed cooling tower allows for high-performance operation of cooling towers of any required size, with any cross section - rectangular, polygonal, round.

Claims (8)

1. A cooling tower comprising a housing with air inlet windows along the periphery in its lower part and water-jet nozzles movably mounted on the collectors in the window opening at an angle towards each other symmetrically relative to the vertical axis of the cooling tower with an offset from the window plane by an angle that ensures the height of the intersection of the jets of liquid torches characterized in that the collectors are made rotatable and provided with blocks of water-jet nozzles fixed to them, and the collectors are located both inside and outside the cooling tower casing and see mounted in horizontal rows at parallel levels at an equal distance from the vertical axis of the tower, the dependence of the limits of the heights of the higher and lower points of intersection of the torch jets on the limits of the values of the angle of the nozzle tilt to the corresponding levels is determined by the formula H ₁ -H ₂ = [(bb ₁ ) (tgα ₁ –tgα ₂ )], where H ₁ is the height of the highest intersection points of the torch jets from the level of the horizontal axes of the collectors, where the torch jets are symmetrical to the vertical axis of the tower; H ₂ - the height of the lowest intersection points of the torch jets from the level of the horizontal axes of the collectors, where the torch jets are symmetrical to the vertical axis of the tower; b ₁ - the distance from the horizontal axis of the nozzle to the vertical axis of the tower for nozzles inside the tower; b ₂ is the distance from the horizontal axis of the nozzle to the vertical axis of the tower for nozzles outside the tower; α ₁ -α ₂ - the limits of the angles of inclination of the nozzles from the corresponding levels. 2. The cooling tower according to claim 1, characterized in that the block of water-jet nozzles is made in the form of a circle with one central nozzle and from two to eight around it. 3. The cooling tower according to claims 1 and 2, characterized in that the collectors are placed in at least two rows and are shifted by 0.4-0.6 m from the window plane into the cooling tower. 4. The cooling tower according to claims 1 to 3, characterized in that the collectors are located outside the cooling tower and are offset by 0.4-0.6 m from the plane of the window. 5. Cooling tower according to claims 1 to 4, characterized in that the nozzle blocks are mounted on the manifold in an amount of 2 to 10 units. 6. The cooling tower according to claims 1-5, characterized in that its cross section is rectangular. 7. The cooling tower according to claims 1-5, characterized in that its cross section is polygonal, for example hexagonal. 8. The cooling tower according to claims 1-5, characterized in that its cross section is made in the form of a circle.