KR100997476B1 - Cooling tower eleminator - Google Patents

Abstract

PURPOSE: A cooling tower eleminator is provided to prevent foreign material and moisture from scattering to the outside of the cooling tower by passing an air the gap between eleminator panels. CONSTITUTION: A cooling tower eleminator includes a plurality of eliminator panels(20), a plurality of spacers(30), and a fixing unit. The eliminator panel forms the path of air which is guided into a cooling tower. The spacer separates the eliminator panels by a certain interval to secure an air path. The fixing unit holds the spacers between the eliminator panels. The eliminator panels have at least two V grooves which are repeated and are opposite to each other.

Description

Cooling Tower Eliminator {Cooling tower eleminator}

The present invention relates to an eliminator for a cooling tower, and more particularly, to minimize foreign substances and water falling out of the cooling tower, and to more strongly to an external load such as a load on which an operator climbs during a cleaning operation for maintenance. The present invention relates to a cooling tower eliminator having a solid support structure capable of withstanding such that the result can be smoothly performed during maintenance work.

In general, industrial and large buildings use cooling towers as heat dissipation equipment for industrial equipment and refrigeration and air conditioning equipment.Effective heat exchange in cooling towers is a final device that emits heat loads from high heat sources to the atmosphere. The performance of the entire system depends on the installation.

A cooling tower is a type of heat exchanger that cools water by directly connecting with outdoor air in order to reuse water used in a condenser of a refrigerator.

In the case of a counter flow cooling tower, which is one of several cooling towers, the air flow moves upward in the vertical direction while passing through the air filler, and the water falls in the vertical direction to release heat contained by the air to exchange heat. This is done.

Specifically, the water tank is located under the cooling tower, and a suction fan for air suction is installed at the uppermost position of the cooling tower, and the eliminator and the cooling water pipe are sequentially installed from the upper side to the lower side so as to be positioned below the suction fan. The cooling water pipe is provided with a spray nozzle, and has a structure in which a filling material is provided between the position under the spray nozzle and the water tank. The air is introduced into the space between the cooling tower and the water tank by the suction fan, thereby filling the filling material and the eliminator. After passing through the cooling tower, the water is injected onto the filler through the injection nozzle, and passes through the filler to be dropped into the water tank. In this process, heat is exchanged to have the temperature required for cooling the refrigerant. In other words, when the high temperature water and low temperature air in contact with the cooling tower, the water is partially evaporated and the heat is taken away, thereby cooling.

The cooling tower, which is a main part of the cooling tower, is provided with a filling material, and a space between the filling material and the suction fan is provided with an eliminator. At this time, the eliminator is formed in a substantially V-shaped plate, by placing a plurality of eliminator side by side in the interior of the cooling tower so as to be located on the top of the filling material, the air coming through the filling material each eli As it passes between the emitters, foreign matter (eg sludge or scale) contained in the air is collected in the eliminator panel. On the other hand, the worker enters the cooling tower and the sludge attached to the eliminator periodically performs cleaning operations such as removing foreign substances such as scales by washing with high pressure water or blowing by blowing with high pressure air.

Whether or not the eliminator can maximize the efficiency of collecting foreign matters in the air is important. Therefore, an eliminator design is required to maximize the collection of foreign matters. In addition, the operator enters and cleans the cooling tower of the cooling tower. In this case, the cleaning work is performed by stepping on the eliminator. Thus, it is necessary to reliably prevent the breakage of the eliminator by firmly supporting it without being deformed by the lifting load.

The present invention is a cooling tower designed to reliably prevent the occurrence of burnout by self-deformation because it can be more robust to the load of the worker's feet for cleaning, etc. while maintaining the maximum efficiency of collecting foreign substances by the simple structure. The purpose is to provide a dragon eliminator.

According to the present invention for solving the above problems, the eliminator panel 20 and the eliminator panel (20) are formed in a plurality of parallel to the inside of the cooling tower to form a passage of air flowing into the cooling tower ( 20 a plurality of spacers 30 to secure the air passage spaced by a predetermined interval, and the cooling tower eliminator including a fixing means for supporting the spacer 30 to be fixed between the eliminator panel 20 In the emitter, the eliminator panel 20 has a shape in which at least two or more v-grooves 200 are repeated in opposite directions, and valleys of the v-grooves 200 are flat portions 202, respectively. The eliminator panel 20 has a structure in which the widths l1 and l2 of the respective planar portions 202 gradually widen as the air inlet side is discharged. There is provided an eliminator for a cooling tower.

Cooling tower eliminator of the present invention is installed between the suction fan of the cooling tower and the filling material on the reservoir, water sprayed from the cooling water pipe installed on the filling of the cooling tower passes through the filling material is collected in the reservoir, and at the same time the top of the cooling tower When the suction fan is driven between the reservoir and the filling material, the suction air is discharged to the upper part, and the air sucked by the suction fan between the filling material at the lower side of the cooling tower and the collecting tank is spaced between the eliminator panel which is the main part of the present invention. As foreign substances and moisture in the air are collected and filtered while passing through the unit, the foreign substances and moisture are prevented from scattering outside the cooling tower.

At this time, the eliminator panel, which is the main part of the present invention, has a structure having a plurality of planar portions, each of which has a valley portion of each v-groove portion, and at the same time, the eliminator panel has a progression from the air inlet side to the discharge side. Since the width of the flat portion of the structure is gradually widened, as the air rises upwards, the area in which the foreign matter in the air contacts the respective flat portions of the eliminator gradually increases, thereby maximizing the foreign matter trapping efficiency. At the same time, it minimizes the phenomenon that water (circulating water) is discharged to the outside of the cooling tower.

In addition, the separation distance between the inclined groove portions adjacent to each other is relatively larger than the separation distance between the inclined groove portions of the v-groove portions of the eliminator panels facing each other, thereby passing through the space portion between the inclined groove portions of the v-groove portions. In this case, the air velocity becomes relatively faster, and when the air passes through the spaces between neighboring plane portions, it causes the process to become relatively slow. Therefore, the foreign matter collection efficiency and moisture collection efficiency can be improved by changing the air flow. You can get even higher.

In addition, in the present invention, the eliminator panel is configured in a double wall shape having a space portion and ribs 26 therein, and at least a position where the v-groove portion and the planar portion are continued from among the plurality of ribs 26 provided in the space portion. The ribs 26 disposed adjacent to the space portion are configured in an S-shape, and thus, the S-shaped ribs 26 can support the worker's lifting load more flexibly, thereby increasing the structural strength of the product. It is possible to increase, and furthermore, because it is possible to considerably reduce the occurrence of burnout caused by external load due to the structural strength improvement, it has an advantage in terms of maintenance and the like.

1 is a perspective view of an eliminator panel, which is a main part of the eliminator of the present invention;
FIG. 2 is a perspective view illustrating a state in which a plurality of eliminator panels illustrated in FIG. 1 are arranged side by side
FIG. 3 shows a spacer holding the space between the eliminator panels shown in FIG.
4 is a front view showing a process of collecting foreign matter due to the air rise between the eliminator panel constituting the present invention
5 is a front view of another embodiment of the present invention.
FIG. 6 is a front view illustrating a process of collecting air by causing air to float between the eliminator panels shown in FIG. 5; FIG.
7 is a front view of the eliminator panel, which is an essential part of another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a perspective view of an eliminator panel, which is a main part of the eliminator of the present invention, FIG. 2 is a perspective view showing a state in which a plurality of the eliminator panels shown in FIG. 1 are arranged side by side, and FIG. 3 is FIG. 4 is a front view showing a process of collecting foreign matter due to air rising between the eliminator panels constituting the present invention. Referring to this, in the present invention, the eliminator panel 20 and the eliminator panel 20 which are installed in a plurality in parallel with each other inside the cooling tower to form a passage of air flowing into the cooling tower are separated from each other by a predetermined interval. An eliminator for a cooling tower comprising a plurality of spacers (30) for securing an air passage and fixing means for supporting the spacers (30) to be fixed between the eliminator panel (20), the eliminator panel ( 20 is configured in a shape in which at least two or more v-grooves 200 are repeated in opposite directions, and valleys of the v-grooves 200 are formed of flat portions 202, respectively. In addition, the eliminator panel 20 is characterized in that the width (1, l2) of each planar portion 202 is gradually widened as it proceeds from the air inlet side to the discharge side.

In the present invention, the eliminator panel 20 is a pair of inclined first inclined wall 24 so as to be symmetrical to both positions of the first planar portion 202a, and any one of the two first inclined walls 24. A second planar portion 202b having one end connected to an end of the first sloped wall 25 of the second sloped portion 25 and a direction symmetrical with respect to one side of the first sloped wall 24 while being connected to the other end of the second planar portion 202b. It has a structure including a second inclined wall 25 extending to be inclined to. The first v-groove 200 is formed by the first flat portion 202a and the pair of first sloped walls 24, and the second sloped wall 25 connected through the second flat portion 202b. The second v-groove 200 is formed by one side first inclined wall 24.

In this case, the eliminator panel 20 is configured in a double wall shape having a space portion and ribs 26 therein, and at least among the plurality of ribs 26 provided in the space portion of the eliminator panel 20. The ribs 26 disposed adjacent to the space portion at the position where the v-groove 200 and the flat portions 202a and 202b are connected may be formed in an S-shape.

The spacer 30 is interposed in at least one v-groove 200 of the v-groove 200 of the eliminator panel 20. Accordingly, the inclined groove portions and the flat portions 202a and 202b of the v-groove 200 of the eliminator panel 20 adjacent to each other are maintained to be spaced apart by the spacer 30 by a predetermined interval. At this time, the spacing distance (D) between the adjacent flat portion (202a, 202b) is relatively larger than the spacing (d) between the inclined groove portion of the adjacent v-groove portion 200.

In other words, the spacer 30 is connected to both ends of the intermediate support portion 32 interposed between the planar portions 202a of the eliminator panel 20 arranged next to each other, It includes a pair of inclined support portion 34 arranged inclined in a symmetrical form and interposed between the inclined groove portion of the V-groove portion 200 of the adjacent eliminator panel 20, the inclined support portion ( The thickness W of the intermediate support portion 32 is made relatively larger than the thickness w of 34, so that the intermediate support portion 32 between the planar portions 202 of each of the eliminator panels 20 is provided. The spacing distance (D) of is maintained relatively large compared to the distance (d) between the inclined grooves adjacent to each other. Reference numeral 32a denotes a through hole formed in the intermediate support part 32 of the spacer 30. The bolt shaft is coupled to penetrate the through hole formed in the spacer part 30 and the through hole formed in the planar part 202a or 202b of the eliminator panel. Arrange the plurality of eliminator panels 20 next to each other and between the suction fan of the cooling tower and the filling material on the reservoir by fastening the two nuts on both sides of the bolt shaft to support the eliminator panel 20 by the nuts. It is possible to assemble the eliminator to be installed in, it is possible to install the eliminator of the present invention between the suction fan and the filling material of the cooling tower via a fixing means such as a bracket. The thickness W of the intermediate support part 32 of the spacer 30 shown in FIG. 3A is about 30 mm, and the thickness w of the inclined support part 34 is about 27 mm. In addition, the width t of the spacer 30 shown in FIG. 3B is about 30 mm.

According to the present invention having such a configuration, when water is injected from the cooling water pipe provided inside the cooling tower in the direction of the filling material, and air rises under the cooling tower by driving the suction fan on the upper side of the cooling tower, elimine which is the main part of the present invention. As the air passes through the space between the data panels 20, foreign matter such as sludge or dust in the air and water may be collected.

In other words, the water sprayed from the cooling water pipe installed on the filling material of the cooling tower passes through the filling material and is collected in the water storage tank. In this case, since the air sucked between the filling material in the lower side of the cooling tower and the sump by the suction fan passes between the eliminator panel 20 which is the main part of the present invention, foreign matter and moisture in the air are collected and filtered. This is to prevent scattering outside the cooling tower.

At this time, the eliminator panel 20, which is the main part of the present invention, is made of a structure having a plurality of planar portions 202a and 202b, in which the valley portions of the v-groove 200 are composed of planar portions 202a and 202b, respectively. At the same time, the eliminator panel 20 has a structure in which the widths l1 and l2 of the planar portions 202a and 202b gradually widen as the air inlet side moves from the air inlet side to the outlet side. As air floats, the area where the foreign matter in the air contacts the flat portions 202a and 202b of the eliminator gradually increases, thereby maximizing the foreign matter trapping efficiency and minimizing the discharge of water (circulating water) out of the cooling tower. It will have an effect.

In addition, the separation distance D between the adjacent flat portions 202a and 202b is relatively greater than the separation distance d between the inclined groove portions of the v-groove 200 of the eliminator panel 20 adjacent to each other. It is configured to be larger, so that the speed of the air is relatively faster when passing through the space portion between the inclined groove portion of the v-groove 200, and the speed when the air passes through the space portion between the adjacent flat portions (202a, 202b) Because it repeatedly causes the process of slowing down, by changing the air flow it is possible to further increase the efficiency of trapping foreign matter and moisture collection.

In addition, in the present invention, the eliminator panel 20 has a double wall shape having a space portion and ribs 26 therein, and at least the v-groove portion 200 of the plurality of ribs 26 provided in the space portion. The ribs 26 arranged adjacent to the space portion at the position where the and flat portions 202a and 202b are connected are configured in an S-shape, and thus, the S-shaped ribs 26 are more flexible to the load on which the worker rises. Since it can hold, it is possible to increase the structural strength of the product.

In other words, the worker enters into the cooling tower to perform the cleaning of the eliminator and steps on the eliminator to perform the cleaning operation. The rib 26 provided in the eliminator panel 20 is S-shaped rib of the eliminator panel 20 when the force which bends in the inclined groove part and flat part 202a, 202b part of the eliminator panel 20 by a load acts, 26) has a more flexible bending operation along the load action direction (up and down action direction) and buffers the load, thereby more reliably preventing the main part of the eliminator from being lifted by the worker. As a result, the structural strength of the product can be further increased, and furthermore, the reliability of the product is higher due to the ability to flexibly support the external load. It is to get the effect.

Meanwhile, FIGS. 5 and 6 show another embodiment of the present invention. In the case of the present invention according to FIGS. 5 and 6, the eliminator panel 20 is symmetrically positioned at both sides of the first planar portion 202a. A pair of inclined first inclined walls 24, second planar portions 202b having one end connected to an end of any one of the first inclined walls 24 on both sides, and the second A second inclined wall 25 extending to be inclined in a direction symmetrical with respect to one side of the first inclined wall 24 at the same time as the other end of the planar portion 202b, and one end of the second inclined wall 25 The third planar wall 202c, which is connected to the other end of the third planar section 202c, and extends to be inclined in a direction symmetrical with respect to the second ramp wall 25; It is configured to include.

Therefore, the first v-groove 200 is formed by the first planar portion 202a and the pair of first sloped walls 24, and the second sloped wall continually connected to the second planar portion 202b. 25 and the second v-groove 200 are formed by one side of the first inclined wall 24, and the third inclined wall 29 and the second inclined wall 25 connected through the third flat portion 202c. As a result, the third V-groove 200 is formed.

Further, in another embodiment of the present invention, the distances t1, t2, t3 of the planar portions 202a, 202b, and 202c are gradually widened, and the ribs 26 are formed in an S-shape. Same as the example.

In another embodiment of the present invention, it is characterized by further increasing the foreign matter collection efficiency by increasing the area to pass through each of the eliminator panel 20 to collect foreign matter and moisture.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various permutations, modifications, and changes can be made without departing from the spirit of the present invention. It will be apparent to those who have it.

20. Eliminator Panel 24. First Slope
25. Second Slope Wall 29. Third Slope Wall
30. Spacer 32. Intermediate Support
34. Inclined Support Section 202. Flat Section

Claims (6)

The plurality of eliminator panel 20 and the eliminator panel 20 to form a passage of the air flowing into the cooling tower is installed in a plurality of parallel to each other inside the cooling tower to secure the air passages In the eliminator for cooling tower comprising a plurality of spacers 30 and fixing means for supporting the spacers 30 to be fixed between the eliminator panel 20, the eliminator panel 20 is At least two or more v-groove 200 is configured in a shape that is repeated in the opposite direction, the valley portion of the v-groove 200 is each composed of a flat portion 202, the eliminator panel 20 Cooling tower eliminator, characterized in that the width (1, l2) of each of the flat portion 202 is gradually widened as it proceeds from the air inlet side to the discharge side.
2. The eliminator panel (20) according to claim 1, wherein the eliminator panel (20) includes a pair of first inclined walls (24) inclined to be symmetrical to both sides of the first planar portion (202a) and the first inclined walls (24) on both sides. The second planar portion 202b having one end connected to one end of the first sloped wall 24 and the other end of the second planar portion 202b, and at the same time, the one side first sloped wall 24. And a second inclined wall 25 extending to be inclined in a symmetrical direction with respect to the first inclined wall 25. The first v-groove portion is formed by the first flat portion 202a and the pair of first inclined walls 24. 200 is formed, and the second v-groove 200 is formed by the second inclined wall 25 and the one side first inclined wall 24 connected to the second planar portion 202b. Eliminator for cooling tower
2. The eliminator panel (20) according to claim 1, wherein the eliminator panel (20) includes a pair of first inclined walls (24) inclined to be symmetrical to both sides of the first planar portion (202a) and the first inclined walls (24) on both sides. The second planar portion 202b having one end connected to one end of the first sloped wall 24 and the other end of the second planar portion 202b, and at the same time, the one side first sloped wall 24. A second inclined wall 25 extending to be inclined in a symmetrical direction with respect to the second inclined wall; a third planar portion 202c having one end connected to the second inclined wall 25; and the other of the third planar portion 202c. And a third inclined wall 29 extending to be inclined in a symmetrical direction with respect to the second inclined wall 25 at an end thereof, and comprising the first planar portion 202a and the pair of first The first v-groove 200 is formed by the first inclined wall 24, and the second inclined wall 25 and the one side first inclined wall 24 connected to each other through the second flat portion 202b. By the second V The groove 200 is formed, and the third v-groove 200 is formed by the third sloped wall 29 and the second sloped wall 25 connected to each other through the third plane portion 202c. Eliminator for cooling tower.
According to claim 1, wherein the eliminator panel 20 is formed in a double wall shape having a space portion and ribs 26 therein, at least the v-groove portion of the plurality of ribs 26 provided in the space portion Cooling tower eliminator, characterized in that the rib (26) disposed adjacent to the space portion of the position where the (200) and the flat portion (202) continues.
The eliminator panel 20 of claim 1, wherein the spacers 30 are interposed between at least one of the V grooves 200 of the eliminator panel 20 and adjacent to each other. The inclined groove portion and the flat portion 202 of the V groove portion 200 are maintained to be spaced apart by the spacer 30 at a predetermined interval, and compared to the distance d between the inclined groove portions of the V groove portion 200 adjacent to each other. Cooling tower eliminator, characterized in that configured so that the separation distance (D) between the adjacent flat portion (202) to each other.
The intermediate support part 32 and the intermediate support part 32 of claim 5, wherein the spacer 30 is interposed between the planar parts 202 of the eliminator panel 20 arranged next to each other. Including a pair of inclined support portion 34 which is arranged to be inclined in a symmetrical form and connected between both ends of the inclined groove portion of the v-groove portion 200 of the eliminator panel 20 adjacent to each other The thickness W of the intermediate support part 32 is relatively greater than the thickness w of the inclined support part 34, and the planar part 202 is formed by the intermediate support part 32. Eliminator for cooling tower, characterized in that the separation distance (D) is maintained relatively large compared to the distance (d) between the inclined groove portion of the v-groove 200.

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