KR100562866B1 - Cooling tower structure and constructing method thereof - Google Patents

Abstract

The present invention relates to a large cooling tower structure installed in an industrial site and a construction method thereof, and more particularly, to form a cooling tower structure by using a stainless steel pipe, which can be used semi-permanently. The present invention relates to a cooling tower structure having excellent economic efficiency and a construction method thereof that can minimize production decrease due to cooling tower replacement.

Accordingly, in the present invention, a plurality of pipe-shaped posts, having a length of 2500 mm to 5000 mm, a plurality of pipe-shaped beams installed in multiple layers between the posts, a connection installed to connect the beams and the posts Cooling tower, characterized in that composed of a brace is installed between the assembly and the connecting assembly in a diagonal direction, the rectangular parallelepiped block consisting of the post and the beam is formed by connecting the cells consisting of 2 to 5 columns and columns, respectively. A structure is provided.

Cooling tower, structure, construction method, post, beam, stainless, assembly

Description

Cooling tower structure and construction method {COOLING TOWER STRUCTURE AND CONSTRUCTING METHOD THEREOF}

1 is a perspective view showing an example of a conventional cooling tower.

Figure 2 is a perspective view showing an example of a conventional cooling tower structure.

Figure 3 is a perspective view showing a unit cell of the cooling tower structure of the present invention.

Figure 4a is a plan view showing a unit cell of the cooling tower structure of the present invention.

Figure 4b is a front view showing a unit cell of the cooling tower structure of the present invention.

Figure 5a is an exploded perspective view showing the 'A' part in Figure 4b.

5B is an exploded perspective view illustrating a portion 'B' in FIG. 4B.

Figure 6 is an exploded perspective view showing the structure of the beam of the present invention.

7a to 7d are perspective views sequentially illustrating a method of constructing a cooling tower structure of the present invention.

Figure 8 is a perspective view of the assembled cooling tower structure of the present invention.

♣ Explanation of symbols for main part of drawing ♣

100: cell 110: beam

111: fastening plate 112: circular plate

120, 160: connection assembly 121, 161: assembly member

122, 162: fastening plate 122a, 122b, 162a, 162b: fastening hole

130: brace 140: post

The present invention relates to a large cooling tower structure installed in an industrial site and a construction method thereof, and more particularly, to form a cooling tower structure by using a stainless steel pipe, which can be used semi-permanently. The present invention relates to a cooling tower structure having excellent economic efficiency and a construction method thereof that can minimize production decrease due to cooling tower replacement.

Cooling towers are used to cool liquids in contact with air, and many cooling towers are counter-flow types in which warmed liquid flows from the top of the cooling tower to the bottom, while air flows to the top by various means to cool the liquid. )to be.

Other forms use cross flow of air and forced air systems. Typical applications for liquid cooling towers are used to cool water to dissipate waste heat in power plants and industrial air conditioning systems.

Most cooling towers have a tower structure. As an example of such a cooling tower, Patent No. 244806 discloses a cooling tower structural assembly comprising two connected cells 32.

1 shows a cooling tower structure assembly as described above, wherein a fan 34, which is protected by a fan protection ring 36, is provided on an upper portion of each cell 32. Motor 38, a gearbox (not shown) is installed, and a liquid dispensing device 49, such as a dispensing header and spray nozzle, and a filling assembly 50 are provided.

The filling assembly 50 is installed below the liquid dispensing device 49 and passes through the filling assembly 50 to allow water to fall into the lower collecting reservoir 46.

At this time, the air is introduced into the cooling tower by the fan 34 and moves through the filling assembly 50, whereby heat transfer occurs between water and air.

Filler of the filling assembly 50 generally has a space for the liquid flows downward and the air flows upward to allow heat and mass transfer between the liquid and the air, as one known type of filler, There is a filler of open-cell clay tile, which has a weight of 60,000 to 70,000 pounds for conventional sized air conditioning cooling towers.

Thus, conventional cooling tower structures are required to be rigidly installed because they must not only bear the load of cooling tower components, including such fillers, but also withstand wind and earthquakes.

2 is a perspective view showing an example of a conventional cooling tower structure. As shown, the cooling tower structure includes a plurality of vertical posts 1 and horizontal beams 2.

The post 1 is divided into several layers by the horizontal beam 2 and a fan and a motor are mounted on the roof to allow air to flow upward.

In the conventional cooling tower structure, the post spacing ('a' or 'b' in FIG. 2) is designed to be about 6 feet (1830 mm), and the horizontal beam 2 and the post 1 in the field are designed. Cooling tower was installed by connecting with bolts and nuts.

In the case of general industrial cooling tower, the material of the structure is made of wood or steel beam, and for the bulky field assembly cooling tower, part of the cooling tower structure is composed of concrete.

However, when wood is used in the structure of the cooling tower has a number of problems. In other words, the wood cooling tower is expensive in the fire protection system, and the life of the wood is shortened because the wood will rot after prolonged exposure to a large amount of air and hot water flowing into the cooling tower.

Thus, in order to increase the lifespan of cooling towers in which wood is used, in the past, the cooling tower structure was constructed of "preserved wood" by anti-corrosion treatment of wood. However, such chemically treated wood may have environmental disadvantages, that is, chemical treatment agents may melt into the water being cooled from the wood and leak.

In addition, when the cooling tower structure is constructed of steel beams, the steel beams are rusted if the steel beams are exposed to high temperature water for a long time.

In addition, the cooling tower structure consisting of some concrete is durable, but expensive and heavy disadvantages. Given the number of cooling towers located on the roof of the building, the weight of the concrete cooling tower is a significant burden on the building design.

Therefore, there is a need for a cooling tower structure that is environmentally friendly and does not have to worry about stability due to corrosion, and has a long lifespan and has excellent durability and economy.

On the other hand, the conventional cooling tower structure, as described above, because the cooling tower is installed by the method of connecting and installing the post 1 and the horizontal beam (2) in the field, the construction process takes a long time due to the large number of assembly processes in the field There was this.

In recent years, the cooling tower structure and construction that can be replaced in the shortest time within the shut-down period in order to reduce the number of downtime due to cooling tower replacement as the number of cooling towers are old in the industrial field and the replacement point is reached. A method has been required.

The present invention has been made to solve the above problems, there is no need to worry about the stability due to corrosion of the cooling tower structure, can be used semi-permanently, and the purpose is to provide a cooling tower structure excellent in durability and economical efficiency. .

In addition, it is possible to quickly assemble the cooling tower structure to significantly reduce the installation time of the cooling tower structure in the field to provide a cooling tower structure construction method that can be replaced in the shortest time within the shutdown (Shut-Down) period. have.

The above object of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

In the present invention, in order to achieve the above object, a plurality of pipe-shaped posts, having a length of 2500 mm to 5000 mm, a plurality of pipe-shaped beams installed in multiple layers between the posts, the beam and the posts Connection assembly is installed to connect the; And a brace installed diagonally between the connection assemblies, wherein the rectangular parallelepiped block formed of the post and the beam is prefabricated by connecting two to five cells each in a horizontal row and a vertical row. This is provided.

The beam and the post is characterized in that the stainless steel pipe or steel pipe or FRP pipe.

In addition, the brace is installed on the vertical surface of each rectangular parallelepiped block constituting the cell, it is characterized in that it is installed in the X-shape.

In addition, the connection assembly is a cylindrical assembly member which is integrally provided with a fastening plate fitted to the post and the fastening hole is formed, and a fastening hole is formed to be coupled to the assembly member and integrally provided at the end of the beam. Consists of plates.

In addition, a cooling tower construction method for achieving the above object is a cell consisting of at least one rectangular parallelepiped block having a span length of 2500 mm or more using a post and a beam made of stainless pipes. Pre-assembling in the field, moving the preassembled first cell to the installation position of the cooling tower, moving the preassembled second cell to a position connectable to the first cell, between the first cell and the second cell. Comprising the step of assembling the beam and connecting the first cell and the second cell, there is provided a cooling tower structure construction method, characterized in that by repeating the operation to complete a plurality of cells assembled prefabricated.

In the step of pre-assembling the cell in the field, the post and the beam are assembled by fastening with a bolt and a nut using a separate connection assembly.

Hereinafter, with reference to the accompanying drawings an embodiment of the cooling tower structure and its construction method of the present invention will be described in detail.

3 is a perspective view illustrating a unit cell of the cooling tower structure according to the present invention, wherein the cooling tower structure according to the present invention is installed between the plurality of posts 140 having a pipe shape and the posts 140 and the post 140. The cell 100 includes one or more rectangular parallelepiped blocks formed of a plurality of pipe-shaped beams 110 installed at predetermined intervals so as to be divided into several layers.

Here, the cell 100 is most preferably composed of two to five rectangular parallelepiped blocks in a horizontal column and a vertical column.

In order to connect the beam 110 and the post 140, a connection assembly 120 and 160 is installed between the beam 110 and the post 140, and supports the beam 110 and the post 140. Brace 130 is installed in the diagonal direction between the connection assembly 120, 160 so as to.

The present invention is to form a cooling tower structure by prefabricating the cells 100 consisting of one or more rectangular parallelepiped block consisting of the post 140 and the beam 110.

4A is a plan view showing a unit cell of the cooling tower structure according to the present invention, and FIG. 4B is a front view showing the unit cell of the cooling tower structure according to the present invention. As shown in FIG. The beam 110 is installed on the six posts 140 to have a rectangular parallelepiped shape of two spaces, and the beam 110 is divided into three layers by dividing each of the posts 140 at regular intervals into three layers. It is installed in three stages including the top.

The beam 110 of the present invention has a length of 2500mm or more, and most preferably has a length of 2500mm ~ 5000mm.

Thus, the post 140 spacing (indicated by 'c' or 'd' in FIG. 4A) is greater than 2500 mm.

As described above, the beam 110 and the post 140 of the present invention are made of stainless steel, and the beam 110 and the post 140 of the stainless steel material are stable due to corrosion of the cooling tower structure. There is no need to worry about, can be used semi-permanently and has a strong durability.

Here, the beam 110 is most preferably an 80 ~ 125A stainless steel pipe, the post 140 is most preferably a 125 ~ 200A stainless steel pipe.

In one embodiment of the present invention, the beam 110 and the post 140 is composed of a stainless steel pipe, but this is the most preferred embodiment, but the present invention is not limited to this, using a steel pipe or a pipe of FRP material Of course, the beam and the post can be configured.

In addition, the cell constituting the cooling tower structure of the present invention, as shown in Figure 4b, the brace 130 in the diagonal direction between the connecting assembly 120, 160 to support the beam 110 and the post 140 Is installed.

The brace 130 is installed on the vertical surface 150 of each rectangular parallelepiped block constituting the cell 100. Here, the vertical surface 150 refers to four surfaces forming the vertical direction in consideration of the block having a rectangular parallelepiped shape, and refers to a virtual surface rather than an actual surface.

In one embodiment of the present invention, the brace 130 is installed in an X shape.

For reference, the brace 130 is preferably installed on all four vertical surfaces of the rectangular parallelepiped block, but in Figure 3 omit the braces installed on both sides in order to help the understanding of the drawings, the structure of the cell 100 is clearly shown It was made.

However, the support 130 is installed on all four vertical planes of the rectangular parallelepiped block is not only the preferred embodiment of the present invention, but the present invention is not limited thereto, and may be selectively installed among the vertical planes forming the rectangular parallelepiped block. to be.

This brace 130 serves to prevent vibration, and provides lateral resistance to wind and seismic loads.

The present invention is not a costly truss (truss) structure as a method for solidifying the cooling tower structure, it is easy to assemble and install, using an economical brace 130, due to such a brace 130 It is possible to construct a block having a spacing of 2500 mm to 5000 mm without a sub-post.

On the other hand, as a means for connecting the beam 110 and the post 140 in the present invention, the connection assembly 120, 160, the connection assembly 120, 160 has a slight shape depending on the installation position This is different.

FIG. 5A is an exploded perspective view of part 'A' in FIG. 4B, and FIG. 5B is an exploded perspective view of part 'B' in FIG. 4B, and the connection assembly 120 illustrated in FIG. 5A is formed of the post 140. Is installed in the middle for connecting the beam 110, the connection assembly 160 shown in Figure 5b is for installing the beam 110 on both sides of the top of the post 140.

The connection assembly 120 installed in the middle of the post 140 has a cylindrical assembly member 121 that is fitted with the post 140 and includes a fastening plate 122 having the fastening holes 122a and 122b. ), And a fastening hole 111a is formed to be coupled to the assembly member 121 and is formed of a fastening plate 111 integrally provided at an end of the beam 110.

The assembly member 121 is provided with a fastening plate 122 only on the lower side, the fastening plate 122 is installed by welding.

Two fastening holes 122b of the fastening holes 122a and 122b of the fastening plate 122 are for connecting with the ends of the brace 130, and the connection assembly 120 is fastened to each other. After aligning the dragon hole, the bolt (not shown) and the nut (not shown) may be used to assemble the post 140, the beam 110, and the brace 130.

In addition, the connecting assembly 160 shown in FIG. 5B also includes a cylindrical assembly member 161 integrally provided with a fastening plate 162 fitted into the post 140 and having fastening holes 162a and 162b formed therein. The fastening hole 111a is formed to be coupled to the assembly member 161 and is formed of a fastening plate 111 integrally provided at an end of the beam 110.

The assembly member 161 is provided with a fastening plate 162 only on both sides, the fastening plate 122 is installed by welding.

The connection assembly 160 is also formed with a fastening hole 162b for connecting with the end of the brace 130, and after fitting the respective fastening holes bolts (not shown) and nuts (not shown) By using the post 140 and the beam 110 and the brace 130 can be assembled.

6 is an exploded perspective view showing the structure of the beam of the present invention, the circular plate 112 is installed at the end of the beam 110 made of a cylindrical pipe to block the beam 110, the fastening plate ( 111 is installed perpendicular to the circular plate 112.

The circular plate 112 and the fastening plate 111 are welded to be integrally provided with the beam 110.

Referring to the construction method of the cooling tower structure of the present invention having such a configuration as follows.

7A to 7D are perspective views sequentially illustrating a method of constructing a cooling tower structure according to the present invention. The span lengths of the horizontal and vertical spans of the post 140 and the beam 110 made of stainless steel pipes are Preassembled in the field a cell 100 composed of at least one rectangular parallelepiped block having 2500 mm or more.

In this case, the post 140 and the beam 110 are assembled by fastening with bolts and nuts using separate connection assemblies 120 and 160.

The prefabricated first cell 100 is moved to the installation position by using the crane 300 (FIG. 7B).

Thereafter, as shown in FIG. 7C, the preassembled second cell 200 is moved to a position connectable to the first cell 100.

As shown in FIG. 7D, the beam 110 is assembled between the first cell 100 and the second cell 200 in both directions by using a bolt and a nut, so that the first cell 100 and the second cell ( 200).

The operation is repeated repeatedly to assemble a plurality of cells prefabricated to complete the cooling tower structure.

8 is a perspective view illustrating the assembled cooling tower structure of the present invention.

According to the construction method of the cooling tower structure of the present invention, since the structure is installed in a rigid structure using a pipe, it is possible to design a cooling tower considerably higher than a general industrial cooling tower. This is used as a method suitable for cooling towers in which a range Δt is required.

It is also suitable for the design of a non-filler type cooling tower using the injection distance from a spray nozzle.

The present invention is a construction method of connecting each block using a crane after designing the post spacing of 2500mm or more in the site as a pre-assembled block, the assembly process of the cooling tower structure in the field can be quickly assembled in the conventional way Compared to that, it can be reduced by more than 1/10.

As described above, the present invention has an effect that can be installed within a minimum construction period because it is pre-assembled in advance before the shut-down and installed using a crane.

This is suitable for industrial-wide cooling tower replacement where replacement work must be completed within a set shutdown period.

In addition, due to the speed of installation, the reduction of production due to the replacement of the cooling tower of the user can be minimized. The main products of the cooling tower are made of stainless pipes, which can be used semi-permanently, thereby reducing waste of resources and worrying about stability due to corrosion of the structure. There is no need for durability and economy.

In addition, the cooling tower is difficult to stop the operation can be replaced by one cell (cell) during normal operation does not affect the operation.

Claims (6)

delete delete delete A plurality of posts in pipe form; A plurality of beams having a length of 2500 mm to 5000 mm and installed in multiple layers between the posts; A cylindrical assembly member integrally provided with a first fastening plate fitted into the post and having a fastening hole formed therein, and a second fastening plate integrally provided at an end of the beam and having a fastening hole formed therein so as to be engageable with the cylindrical assembly member. A connection assembly installed to connect the beam and the post; And Consists of braces installed in the diagonal direction between the connection assembly, Cooling tower structure, characterized in that the rectangular parallelepiped block consisting of the post and the beam is configured by connecting the cells consisting of two to five columns in a horizontal row and a vertical row. Pre-assembling a cell comprising at least one rectangular parallelepiped block having a span length of 2500 mm or more using a post and beam made of stainless pipe and a connecting assembly of claim 4; Moving the prefabricated first cell to an installation position of a cooling tower; Moving the preassembled second cell to a position connectable to the first cell; And Assembling a beam between the first cell and the second cell to connect the first cell and the second cell, Repeatedly repeating the above operation, the cooling tower structure construction method characterized in that the completion by connecting a plurality of cells prefabricated. delete

Images