KR102162553B1 - A filling material having protrusions for preventing scattering of condensation - Google Patents

Abstract

The present invention relates to a filler, and more particularly, to a filler having protrusions formed on the front and rear surfaces of the filler to prevent scattering of cooling water.
In the present invention, a filler having a plurality of protrusions is formed on both sides of a plate-shaped filler, and air containing cooling water collides with the protrusions and the cooling water having a heavy mass is separated from the air. It is for the purpose of providing.

Description

A filling material having protrusions for preventing scattering of condensation

The present invention relates to a filler installed to perform heat exchange by contacting air in order to reuse heated cooling water installed inside a cooling tower, and more particularly, to a filler formed with protrusions on the front and rear surfaces of the filler to prevent scattering of the cooling water. will be.

In general, a cooling tower directly cools the heat generated from the production process of the plant or various mechanical devices used in the plant with water in a water-cooled heat exchange device.It receives heat from various mechanical devices and directly cools the heated water with air in the atmosphere to reuse the heated water. Or it refers to a heat exchange device that cools heated water by indirect contact.

Cooling towers are largely divided into counter-flow cooling towers and cross-flow cooling towers according to the flow of air and water. In cross-flow cooling towers, air moving horizontally through louvers installed on both sides of the cooling tower and water moving vertically cross at right angles to achieve heat exchange. It is the most widely used.

In order to improve the cooling efficiency, a filler is installed inside the cooling tower, which determines the cooling efficiency of the cooling tower. The cooling tower filler is generally formed as a filler assembly in which a plurality of plate-shaped fillers are stacked and installed in the cooling tower.

Therefore, the filling material should be distributed evenly in the downward direction while delaying the high-temperature coolant sprayed from the top of the filling material by the spray nozzle to flow down, and allow the air that has entered through the louver to move, but the air is not in the filling material. It is preferable that it is formed in a structure that allows it to stay for a long time so that it can be in contact with the high temperature cooling water for a long time.

At this time, when small water droplets of cooling water are discharged to the outside together with air, it is called scattering.If discharged to the outside, maintenance costs increase due to the loss of cooling water, and the scattered water droplets cause slippery on the floor due to condensation around the cooling tower in winter There is a problem.

1. Korean Patent Publication No. 10-1384359 ("Cooling tower filler", 2014.04.04.)

The present invention has been conceived to solve the above problems, and an object of the present invention is to form a plurality of protrusions on both sides of a plate-shaped filler, and air containing cooling water collides with the protrusions, and the cooling water having a heavy mass is air It is to provide a filler having a protrusion for preventing scattering of cooling water so that it can be separated from.

In the filler having a protruding portion for preventing scattering of the coolant of the present invention, a filler having a plate-shaped plate body and a unit filler including uneven parts formed on both sides of the plate body are stacked and arranged, wherein the unit filler comprises: A protrusion formed on one surface of the unit filler, including at least one first protrusion protruding in one direction, and at least one second protrusion formed on the other surface of the unit filler, protruding in the other direction Including; wherein the first protrusion and the second protrusion are formed to extend across a plurality of flow paths along the height direction of the unit filler, and cross the flow direction of the air moving parallel to the ground in a direction orthogonal to the And a height protruding upward of the first protrusion is higher than a floor of the concave-convex part, and a depth protruding downward of the second protrusion is deeper than a valley of the concave-convex part. It is characterized in that the cooling water is separated from the airflow by colliding with the second protrusion to prevent scattering of the cooling water.

In addition, the guide portion is characterized in that the vertical cross section is a honeycomb (honeycomb) shape.

In addition, the guide unit is characterized in that it is formed by repeating protrusion and depression along the length direction of the unit filler.

In addition, the unit filler is characterized in that a coupling protrusion is formed on one surface and a coupling groove is formed on the other surface.

In addition, the unit filler is characterized in that a cover is installed on the upper end, and is formed to cover a selected area of the interval between the unit fillers.

The filling material having protrusions for preventing scattering of the coolant according to the present invention according to the above configuration has a plurality of protrusions formed on both sides of the plate-shaped filler, so that the air containing the coolant collides with the protrusions and has a higher mass The coolant can be separated from the air to prevent scattering.

1 is a perspective view of a filler according to an embodiment of the present invention
Figure 2 is a bottom view of a filler according to an embodiment of the present invention
Figure 3 is an enlarged view of the bottom of the filler according to an embodiment of the present invention
4 is a side cross-sectional view of a filler according to an embodiment of the present invention
5 is a schematic diagram of a cooling tower in which a conventional filler is installed
6 is a schematic diagram of a cooling tower in which the filler of the present invention is installed
7 is a plan view of a filler according to a modified example of an embodiment of the present invention

Hereinafter, an embodiment of the present invention as described above will be described in detail with reference to the drawings.

1 shows a perspective view of a filler according to an embodiment of the present invention. As shown in FIG. 1, the filler 200 of the present invention is formed by intersecting and intersecting unit fillers 210 in the form of plates.

The surface of the unit filler 210 is formed in an uneven shape with valleys and floors formed, and the unit fillers 210 are combined with each other so that the cross-sections of both ends of the filler 200 are formed in a honeycomb shape. It is desirable.

It is preferable that one end of the filler 200 is formed as an air inlet 270 through which air is introduced, and the other end is formed as an air outlet through which the air moved along the length direction of the filler 200 is discharged.

On the surface of the unit filler 210, a guide unit 221 of a predetermined length protruding and recessed along the height direction of the unit filler 210 is formed, and the unit filler 210 is coupled to the filler ( As 200 is formed, the guide unit 220 in the form of a passage through which a fluid can move is formed by contacting the guide units 221 formed in each of the unit fillers 210.

The guide part 220 is for guiding the flow of air passing through the filler 200 and will be described later with reference to FIGS. 5 and 6.

A coupling protrusion 240 is formed on the surface of the unit filler 210 so that each of the unit fillers 210 can be easily coupled, and the coupling protrusion 240 is a coupling groove formed in the unit filler 210 It is characterized in that the unit filler 210 is coupled by fitting to 250.

In other words, the unit filler 210 shown in the front of FIG. 1 is referred to as a first unit filler, and the coupling protrusion 240 and the coupling groove 250 of the first unit filler and the first unit filler The coupling protrusion and the coupling groove of the second unit filler located closest to the first unit filler are formed in opposite left and right positions, and the second unit filler is in the coupling groove of the first unit filler. The first unit filler and the second unit filler are combined by inserting the coupling protrusion of the filler material 200, and the filler material 200 is formed by repeating this.

In addition, a plurality of protrusions 230 for preventing scattering are formed on both surfaces of the unit filler 210. Scattering means that small water droplets of cooling water are discharged to the outside together with air.If discharged to the outside, maintenance costs increase due to the loss of cooling water, and the scattered water droplets cause slippery on the floor due to condensation around the cooling tower in winter. There is this.

The filler 200 of the present invention is to solve the above problems, and the protrusion 230 capable of colliding with air is formed on the surface of the filler 200. The protrusion 230 is formed to protrude a predetermined length from both surfaces of the unit filler 210 and is formed along the height direction of the unit filler 210.

The protrusion 230 formed on the filler of the present invention will be described in more detail with reference to FIGS. 2 and 3.

2 shows a bottom view of a filler according to an embodiment of the present invention. As shown in FIG. 2, the surface of the unit filler 210 is formed in an uneven shape, and the guide unit 221 for forming the guide part 220 is formed in the center. In addition, a plurality of the protrusions 230 protrude a predetermined length on both surfaces of the unit filler 210. It is preferable that the protruding length of the protrusion 230 is higher than the unevenness formed on the surface in consideration of the flow of coolant and air, and is formed lower than the height of the guide unit 221.

The protrusion 230 will be described in more detail with reference to FIG. 3. 3 is an enlarged view of a bottom surface of a filler according to an embodiment of the present invention. As shown in FIG. 3, air moves the gap formed between the unit fillers 210 and is sprayed from the spray nozzle 300 to contact the cooling water moving along the irregularities formed on the surface of the unit fillers 210. Heat exchange.

At this time, the air and the coolant are in contact and the small water droplets of the cooling water are included with the air and move, and the first protrusion 231 is the unit filler 210 so that the air moves and collides to separate the water droplets contained in the air. ) Is convexly formed on the surface.

At this time, the height of the first protrusion 231 is formed higher than the top of the unevenness formed on the surface of the unit filler 230, so that when air passes through the gap formed between the unit fillers 210, the first protrusion It must hit (231).

Air collides with the first protrusion 231 and droplet particles that are relatively heavier than air are separated from the air, and the separated droplet particles follow the irregularities formed on the surface of the unit filler 210 to the lower portion of the unit filler 210 Go to.

In addition, in the filler 200 of the present invention, the second protrusion 232 is formed to be convex downward on the surface of the unit filler 210 in order to more effectively prevent scattering.

At this time, the height of the second protrusion 232 is formed lower than the valley of the unevenness formed on the surface of the unit filler 230, so that when air passes through the gap formed between the unit fillers 210, the second protrusion It must hit (232).

Water droplets that collide with the second protrusion 232 and are relatively heavier than air may be separated from the air to prevent scattering.

In other words, the unit including the first protrusion 231 formed convex upward from the surface of the unit filler 210 and the second protrusion 232 concave downward from the surface of the unit filler 210 The protrusion 230 is formed on both sides of the filler 210 so as to collide with air.

In this case, a plurality of the first protrusions 231 and the second protrusions 232 may be formed along the length direction of the unit filler 210.

A plurality of the unit fillers 210 are combined to form the filler 200, whereby at least one gap between the unit fillers 210 is also formed. In the filler 200 of the present invention, since the protrusion 230 including the first protrusion 231 and the second protrusion 232 is formed on both sides of the unit filler 210 It is characterized in that it always collides with the protrusion 230 even if it flows into at least one selected of the intervals between the unit fillers 210 and moves.

The filler of the present invention has the function of preventing the fluid flow from deflecting by forming the guide unit 220 to guide the movement of air by the guide unit 221 formed on the surface of the unit filler 210 as described above. You can also have.

More specifically, Figure 4 shows a schematic diagram of a cooling tower in which a conventional filler is installed. As shown in FIG. 4, the conventional cooling tower 10 is a cross-flow type cooling tower, with fillers 20 installed on both sides, and a plurality of spray nozzles 30 for spraying high-temperature cooling water on the top of the filler 20 Is installed. The coolant sprayed from the spray nozzle 30 flows from the top to the bottom of the filler 20.

In addition, air is injected into the cooling tower 10 from the outside, and the air passes through the filler 20 in a direction perpendicular to a direction in which the cooling water moves. At this time, the high-temperature cooling water flowing from the top to the bottom of the filler 20 and the air injected from the outside directly contact each other for heat exchange, and the air passing through the filler 20 is blown at the top of the cooling tower 10 It is discharged back to the outside by the fan 40.

However, the air introduced into the conventional cooling tower 10 is deflected in the direction of the blowing fan 40 without moving in the longitudinal direction of the filler 20 by the wind generated by the blowing fan 40 and moves. .

Because the cooling water is also deflected and flows in the inner direction of the cooling tower 10 along the direction of the air by the flow of air, the lower side of the side of the filler 20 is an area where heat exchange is not performed in the filler 20 because cooling water does not flow. (Dead Zone) occurs.

Accordingly, there is a problem in that the area for heat exchange in the filler 20 is reduced, and thus, heat exchange efficiency is also lowered. The cooling tower filler of the present invention was devised to solve the conventional problem and will be described in more detail with reference to FIG. 5.

5 is a schematic diagram of a cooling tower in which the filler of the present invention is installed. As shown in FIG. 5, the cooling tower 100 in which the filler 200 of the present invention is installed is a cross-flow type cooling tower, the filler 200 is installed on both sides, and high-temperature cooling water is supplied on the top of the filler 200. A plurality of spray nozzles 300 for spraying are installed. The coolant sprayed from the spray nozzle 300 flows from the top to the bottom of the filler 200.

In addition, air is injected into the cooling tower 100 from the outside, and the air passes through the filler 200 in a direction perpendicular to a direction in which the cooling water moves. At this time, the high-temperature cooling water flowing from the top to the bottom of the filler 200 and the air injected from the outside directly contact each other to heat exchange, and the air that has passed through the filler 200 is blown at the top of the cooling tower 100 It is discharged back to the outside by the fan 400.

At this time, in order to prevent the air passing through the filler 200 from being deflected by the blowing fan 400, the filler 200 is formed in the height direction of the filler 200, and guides the movement of air. At least one guide part 220 is formed.

Because air is not deflected in the direction of the blower fan 400 by the guide unit 220, but passes through the guide unit 220 and the flow of air is redistributed, heat exchange is performed in all regions of the filler 200.

6 shows a side cross-sectional view of a filler according to an embodiment of the present invention. FIG. 6 is a cross-sectional view of a portion A-A' of FIG. 1, and as shown in FIG. 5, the cross-section of the guide part 220 is preferably a honeycomb shape like the cross-section of the air inlet 270.

Since the air flowing through the air inlet 270 and passing through the filler 200 tries to move to a place that receives less resistance than a place that receives a lot of resistance when moving, the gap formed by each of the unit fillers 210 are combined The air and the cooling water passing through the conventional filler 20 were deflected and moved because it is the side where the air is less resistant to the air being discharged to the outside through the blower fan 400 rather than passing through.

However, the guide unit 220 is formed in the center of the filler 200 of the present invention in the form of a passage through which air can move by the guide unit 221, and the air passes through the guide unit 220 Therefore, air is evenly redistributed to the filler material 200 so that heat exchange can be performed in the entire area of the filler material 200.

In other words, the guide unit 221 formed by protruding or depressing to form the guide part 220 is formed to have a longer protruding or depressed length than the unevenness formed entirely on the surface of the unit filler 210, Since the air moves through the guide unit 220 than passing through the gap between the unit fillers 210, the resistance is lower than that of the air moving to the upper part of the filler 200. ), the amount of air moving toward it becomes larger.

Therefore, since the air that has passed through the guide unit 220 without being deflected toward the blowing fan 400 is redistributed to the filler 200, heat exchange efficiency in which heat exchange is performed in the entire area of the filler 200 This high cooling tower filler can be provided.

In addition, at least one guide part 220 may be installed in the middle of the filler 200 to serve as a support for supporting the filler 200. Since the unit filler 210 is a thin plate, deformation is likely to occur when cooling water having a temperature higher than the appropriate temperature for use is injected from the spray nozzle 300 or when there is a large amount of sludge contained in the cooling water. However, since the guide part 220 serves as a support in the middle, it is possible to provide a cooling tower filler having high durability.

In addition, as described above, the guide unit 221 forming the guide part 220 has a longer protrusion and depression than the irregularities formed on the surface of the unit filler 210, so that the air like the protrusion 230 It can also act as a stumbling jaw that collides when moving.

7 shows a bottom view of a filler according to a modified example of an embodiment of the present invention. As shown in FIG. 7, a cover 260 is formed in a gap formed between each of the unit fillers 210.

The cover 260 is formed on the upper end of the filler 200 and is formed to cover a region selected from the intervals formed when each of the unit fillers 210 are combined, and the cover 260 includes the filler 200 This is to prevent the air passing through) from being discharged to the outside when it moves to the top of the filler 200.

In other words, even if the air moves to the top of the filler 200, the cover 260 receives a lot of resistance when it moves in the direction of the blowing fan 400, so that the amount of air discharged to the outside can be reduced.

At this time, the cover 260 may be formed to cover the entire area or a partial area of the gap between the unit fillers 210, and as shown in FIG. 7, the gap between each of the unit fillers 210 is alternately May be formed or formed over the entire gap.

However, when formed over the entire gap, the cover 260 is preferably formed to cover a partial area of the gap between the unit fillers 210.

The technical idea should not be interpreted as limited to the above-described embodiment of the present invention. As well as a variety of application ranges, various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, these improvements and changes will fall within the scope of protection of the present invention as long as it is apparent to those skilled in the art.

10, 100 cooling towers
20, 200 filler
30, 300 spray nozzle
40, 400 blowing fan
210 units of filler
220 Guide part
221 guide unit
230 protrusion
231 first protrusion
232 second protrusion
240 mating protrusion
250 mating groove
260 cover
270 air inlet
280 air outlet

Claims (6)

In a filler in which a unit filler including a plate-shaped plate body and irregularities formed on both sides of the plate body is stacked and arranged,
The unit filler,
It is formed on one surface of the unit filler, at least one first protrusion protruding in one direction, and at least one second protrusion formed on the other surface of the unit filler, protruding in the other direction. projection part;
Including,
The first protrusion and the second protrusion are formed to extend across a plurality of flow paths along the height direction of the unit filler, and are formed to cross the flow direction of the air moving parallel to the ground and in a direction orthogonal,
A height protruding upward of the first protruding part is higher than a floor of the uneven part, and a depth protruding downward of the second protruding part is formed deeper than the valley of the uneven part,
The filling material, characterized in that the air flow collides with the first protrusion and the second protrusion to separate the cooling water from the air flow, thereby preventing scattering of the cooling water.
The method of claim 1, wherein the unit filler,
A guide unit formed on both surfaces of the unit filler, which is recessed or protruded along one direction of the unit filler to guide the flow of the fluid;
Including,
A filler, characterized in that as the plurality of unit fillers are arranged, the guide unit is coupled to each other, but is formed in a passage shape to form a guide part that guides the movement of the fluid.
The method of claim 2, wherein the guide part,
Filling material, characterized in that the vertical cross section is a honeycomb (honeycomb) shape.
The method of claim 3, wherein the guide unit,
Filling material, characterized in that formed by repeating the protrusion and depression along the length direction of the unit filler.
The method of claim 1, wherein the unit filler,
Filling material, characterized in that a coupling protrusion is formed on one side and a coupling groove is formed on the other side.
The method of claim 1, wherein the unit filler,
A filler, characterized in that the cover is installed on the upper end, and formed to cover a selected area of the interval between the unit fillers.

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