KR200443396Y1 - Nozzle for spraying-type cooling tower - Google Patents

Abstract

The present invention relates to a water spray nozzle for use in a non-powered spray cooling tower.

The non-powered spray cooling tower is sprayed with a nozzle to cool the water circulated inside the cooling tower without installing a driving unit such as a Fan motor belt pully, which is found in the existing cooling tower.

The present invention relates to a cooling water spray nozzle for cooling the circulating water in a non-powered cooling tower. The cooling water sprayed through the nozzle is sprayed in a fan-shaped streamline shape, and is mixed with gas (air) by splitting into small droplets at the same time as the spraying. It is mixed with the air in the state, and while mixing with the air to instantly absorb the heat energy of the air to lower the ambient temperature to cool the heat exchanger flowing circulating water.

The present invention has the following configuration.

In the cylindrical metal nozzle 10 having a water spraying portion 11 at the front end and a fixed body 12 at the rear end, and a water spraying hole 13 at the water spraying 11 at the front end,

It has a slanted inclined surface 15 at both the left and right sides in the center of the upper surface of the water spraying portion 11 of the tip, "V" shaped groove 17 is formed in the center of the inclined slanted surface 15, the inclined slanted surface 15 An elliptical water spraying hole 13 is formed between the “V” shaped grooves 17), and the left and right sides of the water spraying portion 11 have a cutout surface 19, and below the water spraying portion of the tip ( 11) has an upper circular border 14 that separates the fixed body 12 of the rear end and has a lower circular border 16 at the lower portion of the fixed body 12, the upper circular border 14 and the lower circular border The fixed body 12 between the 16 is composed of a gently inclined cylindrical shape, the packing body 21 is fastened to the fixed body 12 is coupled to the cooling water pipe 31, frame 32 And band clamp (33) is fixed.

In addition, the inner inlet of the nozzle 10 has a water inflow portion (a) having the same diameter and a cross-sectional reduction portion (b) in which the inner diameter is narrowed, and the cross-section is gradually elliptical between the cross-section reduction portion (b) and the water spray hole. It is to have a water injection portion (c) formed into a phase.

Powerless cooling towers, nozzles,

Description

Nozzle for spraying-type cooling tower

1 is a perspective view of the present invention.

2 is a front view of the present invention.

3 is a cross-sectional view taken along the line Z-Z of FIG.

Figure 4 is a perspective view of the use state of the present invention.

5 is a cross-sectional view of the use state of the present invention.

6 is a schematic cross-sectional view of a non-powered cooling tower.

The present invention relates to a water spray nozzle for use in a non-powered spray cooling tower.

The non-powered spray cooling tower is sprayed with a nozzle to cool the water circulated inside the cooling tower without installing a driving unit such as a Fan motor belt pully, which is found in the existing cooling tower.

The non-powered cooling tower cools the circulating water with latent heat of evaporation while the cooling water injected through the nozzle contacts the surrounding gas (air). The non-powered cooling tower does not have a driving unit, so the noise and vibration are small so that a comfortable environment is maintained during operation of the cooling tower. This has the advantage of simple structure and easy maintenance.

The performance of a non-powered cooling tower depends on the smoothness of mutual heat exchange between the cooling water injected into the cooling tower having a constant space and the gas (air) therein.

Heat transfer (exchange) inside the cooling tower is affected by the spraying state of the cooling water sprayed through the nozzle, the particle size of the cooling water, and the spraying speed of the cooling water.

That is, the performance of the cooling tower is determined by the change in the space distribution and mass flow rate of the injected cooling water and the amount of surrounding gas (air) introduced by the spray.

Therefore, in order to design and predict the performance of the cooling tower, it is necessary to grasp the average particle diameter, space distribution and spray characteristics of the cooling water spray used in the spray system.

More specifically, the spray of cooling water, which is a major factor that determines the performance of a non-powered cooling tower, refers to a state in which a certain amount of liquid (cooling water) is sprayed into small droplets (liquid particles), and the sprayed cooling water is The area is increased in contact with the gas (air), and the temperature in the cooling tower is lowered by absorbing heat in the air while being in contact with the air.

Spraying the coolant due to the cooling performance is determined by the spray state of the coolant, that is, atomization drop size distribution, breakup length, spray angle (spray angle), penetration length Nozzle structure, shape and water pressure are the major factors that determine the performance of a cooling tower.

The present invention relates to a water spray nozzle which is the main factor that determines the performance of the cooling tower.

The present invention relates to a cooling water injection nozzle for cooling the circulation water in a non-powered cooling tower.

In the non-powered cooling tower, the cooling efficiency is increased as the particle diameter of the sprayed water is smaller, the surface area per unit volume is increased, so that the evaporation is actively progressed, thereby increasing the temperature drop and increasing the response speed to the temperature change.

According to the present invention, the coolant sprayed through the nozzle is sprayed into a fan-shaped streamline with the hole of the nozzle as an ellipse shape. Cooling water jetting liquid sprayed in the form of small particles absorbs the heat energy of the air while mixing with air, lowers the ambient temperature, and cools the heat exchanger through which the circulating water flows.

The present invention is aimed at effectively cooling the temperature in the cooling tower by instantaneous adsorption of thermal energy of the air by mixing it with the surrounding air as the cooling water is injected into the nozzle, split into small particles, and the injection length is increased. It is.

In the cylindrical metal nozzle 10 having a water spraying portion 11 at the front end and a fixed body 12 at the rear end, and a water spraying hole 13 at the water spraying 11 at the front end,

On the outer circumferential surface of the water spraying portion 11 of the front end has a slanted surface 15 inclined toward the center on both sides, a "V" shaped groove 17 is formed in the center of the inclined slanted surface 15, and the inclined slanted surface An elliptical water spraying hole 13 is formed between the “V” grooves 17 of 15 and the outer circumferential surface of the water spraying portion 11 has cutouts 19 on both sides, and the water spraying portion 11 ) Has an upper circular border 14 that separates the water spraying portion 11 and the fixed body 12, and has a lower circular border 16 below the outer peripheral surface of the fixed body 12, the upper circular border ( 14) and the fixed body 12 between the lower circular rim 16 is composed of a gently inclined cylindrical shape, after the packing 21 is fastened to the fixed body 12, it is coupled to the cooling water pipe 31 Will be fixed to the frame 32 and the band clamp 33.

Further, inside the nozzle 10, a first inner diameter A constituting a water inflow portion a having the same diameter, and a second inner diameter B constituting a first cross-sectional reduction portion b whose inner diameter is gradually reduced. And a second cross-sectional reduction part (c) having a third inner diameter (C) gradually narrowing toward the water injection hole (13), and between the second inner diameter (B) and the third inner diameter (C). It is to have a stone step (d) to vortex.

In the figure, reference numeral 41 denotes a non-powered cooling tower, and 42 denotes a heat sink.

The material of the nozzle is preferably brass and the packing 21 is made of rubber.

The present invention having such a structure will be described in more detail and at the same time as follows.

After the packing 21 is coupled to the fixed body 12 of the nozzle 10 of the present invention, it is fitted into the coupling hole of the cooling water pipe 31 in the non-powered cooling tower 41, and the frame 32 is positioned on the nozzle 10. After being combined, it is fixed by the band clamp 33.

The nozzle 10 fixed to the cooling water pipe 31 sprays the cooling water in a fan shape, and the cooling water sprayed cools the circulating water supply pipe 42 in the non-powered cooling tower 41.

The heat sink 42 is composed of a plurality of aluminum plates to aggregate the cooling water sprayed from the nozzle and cool the cooling water again.

The fixed body 12 of the nozzle 10 according to the present invention is the packing 21 is coupled to the coupling hole of the cooling water pipe 31, the front center of the water injection portion 11, which is the tip of the nozzle 10 Since the water spray hole 13 is formed in an elliptical shape, the cooling water sprayed through the elliptical shape is sprayed into a fan shape having a long vertical width and a narrow left and right width.

The cooling water sprayed in the fan shape as described above instantly lowers the temperature while absorbing and evaporating heat in the air flowing into the non-powered cooling tower 41.

The coolant sprayed in the fan shape is cooled again in the heat sink 42 having a predetermined space with the coolant pipe 31 and aggregates the coolant.

In the above, the cooling water sprayed into the fan shape by the elliptical water spray hole 13 has a long upper and lower width and a narrow left and right width, so that the heat energy of the gas (air) attracted to the cooling tower 41 is instantaneously adsorbed. By lowering the temperature, the sprayed cooling water is increased because the injection pressure is increased, the injection speed is increased, the length of the injection is long.

Therefore, the cooling water effectively lowers the temperature in the cooling tower during spraying, and is rapidly combined with air to cool the cooling water due to the high injection speed.

Further, the nozzle 10 of the present invention has "V" shaped grooves 17 on both sides of the elliptical water spray hole 13 formed in the center, and both sides of the "V" shaped grooves 17. It has an inclined slope 15.

Cooling water sprayed from the nozzle 10 having the structure as described above is long and vertical width, the left and right width is sprayed in a narrow fan shape, the water spray hole 13 is the left and right inclined slope 15 and the "V" shape The groove 17 has an edge of the elliptical shape of the water spray hole 13 to form sharp edges, so that the outer side of the sprayed cooling water is smaller in particle size than the inner side of the central portion, thereby rapidly advancing with gas (air). The mixture absorbs and cools the heat in the air.

In the nozzle for injecting water or other fluid, the injection flow rate increases with increasing injection pressure, and when the injection pressure is constant, the injection flow rate increases with a nozzle having a large cross-sectional area of the nozzle.

However, as the flow rate increases, the change amount decreases or becomes constant as the flow rate increases, and when the injection pressure is constant, the larger the cross-sectional area of the nozzle outlet is, the smaller it appears. In the case of elliptical shape, this theory does not exactly match.

As shown in the present invention, when the water spray hole 13 of the nozzle has an elliptical shape, and the edge of the water spray hole has an angled corner, the spray form becomes elliptical and the liquid of the spray liquid outside the center portion. The enemy has a smaller particle shape, and the jet flow rate is faster than a circular nozzle of the same size.

In particular, the present invention is the first inner diameter (A) constituting the water inlet (a) having the same diameter inside the nozzle 10, and the inner diameter is reduced to form a second inner diameter (b) B) and a second cross-sectional reduction part c having a third inner diameter C, the inner diameter of which is gradually narrowed toward the water spray hole 13,

The cooling water flowing into the nozzle is increased in the first cross-sectional reduction portion (b) where the inner diameter is reduced through the water inflow portion (a) of the same diameter, the first cross-sectional reduction portion (b) and the second cross-sectional reduction portion By the inner edge on the boundary line of (c), the vortex which is an unstable state of cooling water is generated.

In addition, the cooling water is rotated while the flow rate is increased while passing through the second cross-sectional reduction part (c) whose diameter is reduced, and is sprayed in a fan shape while being sprayed through the elliptical water injection hole (13).

The cooling water sprayed as described above is neatly sprayed because the cooling water sprayed is constituted by a linear state in which the edge of the water spray hole 13 of the nozzle protrudes inward.

The fixed body of the nozzle of the present invention is the packing is coupled, coupled to the coupling hole of the cooling water pipe, the water spray hole formed in the front center of the water spraying portion, which is the tip of the nozzle becomes an elliptical shape, so that the cooling water sprayed through the upper and lower The width is long and the cooling water is sprayed into a narrow fan shape.

In addition, the edges of the elliptical water spray holes form sharp edges, so that the outer side of the sprayed cooling water becomes smaller than the inner side of the central cooling water particles, which is rapidly mixed with the gas (air) to absorb heat in the air. To cool.

Thus, the cooling water sprayed into the fan shape by the elliptical water spray hole has a long upper and lower width and a narrow left and right width. Therefore, the cooling water is instantaneously adsorbed the heat energy of the gas (air) flowing into the cooling tower to lower the temperature. Since the cooling water is increased in the injection pressure, the injection speed is increased, the injection length is long.

In addition, the cooling water injected into the nozzle is a very useful design to increase the cooling efficiency by lowering the temperature in the non-powered cooling tower due to the injection of small particles and effectively cooling the circulation water supply pipe.

Claims (2)

In the cylindrical metal nozzle 10 having a water spraying portion 11 at the front end and a fixed body 12 at the rear end, and a water spraying hole 13 at the water spraying 11 at the front end, On the outer circumferential surface of the water spraying portion 11 and has the inclined surface 15 inclined toward the center on both sides, a "V" shaped groove 17 is formed in the center of the inclined slope 15, the inclined slope 15 An elliptical water spraying hole 13 is formed between the “V” shaped grooves 17), and an outer peripheral surface of the water spraying portion 11 has a cutout surface 19 on both sides, and below the water spraying portion 11. It has an upper circular border 14 that separates the water injection portion 11 and the fixed body 12, and has a lower circular border 16 below the outer peripheral surface of the fixed body 12, the upper circular border 14 and the lower The fixed body 12 between the circular rim 16 is a water spray nozzle for a non-powered cooling tower, characterized in that consisting of a gently inclined cylindrical shape The inside of the nozzle (10) according to claim 1, wherein the first inner diameter (A) constituting the water inflow portion (a) having the same diameter and the first sectional reduction portion (b) constituting the inner diameter are gradually reduced. 2 has a second cross-sectional reduction portion c of a third inner diameter C, the inner diameter of which is gradually narrowed toward the inner diameter B and the water injection hole 13, and the second inner diameter B and the third inner diameter ( C) water jet nozzle for a non-powered cooling tower characterized in that it has a step (d) for vortexing the cooling water.

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