KR20220162457A - Cfrp block module type cooling tower - Google Patents

Abstract

An objective of embodiments of the present invention is to provide a cooling tower of a carbon fiber reinforced plastic (CFRP) block module type which forms a cooling tower structure as a block type to have the effect of construction cost reduction by reducing raw materials and shortening construction periods, and forms a lightweight strength reinforcement block structure without concern for corrosion to quickly and safely allow modular assembly and reduce the risk of fire and the danger of high-place work at a site to prevent accidents. According to an embodiment of the present invention, the cooling tower of a CFRP block module type comprises: a block cell of a rectangular frame structure shape including carbon fiber reinforced plastic (CFRP); a block module formed by coupling at least one block cell in a plane direction; and a module unit allowing the block modules to be selectively coupled and separated from each other in a height direction to form a plurality of levels in a stacked arrangement structure of a preset form to support a corresponding cooling device.

Description

CFRP block module type cooling tower {CFRP BLOCK MODULE TYPE COOLING TOWER}

The present invention relates to a CFRP block module type cooling tower.

In general, a cooling tower is a cooling facility that exchanges heat generated from a high-temperature cooling medium heat-exchanged in a power generation facility and an air conditioning facility at a low temperature, and is formed in a tower structure and is installed on the ground or on the roof of a building. The cooling tower is used to support a corresponding cooling device by forming a structure with a combination structure of a plurality of vertical posts and horizontal beams, and to cool a high-temperature liquid. For example, a cooling tower directs hot liquid to flow from the top of the tower to the bottom, and conversely, air is guided to flow from the bottom to the top to cool the liquid.

In the case of on-site assembly cooling towers, most of them were composed of steel sections, FRP drawn section sections, and concrete. In this cooling tower structure, the post spacing was designed to be within or outside the set length, and the cooling tower was installed at the site using bolts and nuts for horizontal beams and posts. However, since the cooling tower structure is connected and installed at the site, there are many assembly processes of the cooling tower at the site, so skilled labor is required and the construction period is long. Therefore, there is a demand for technology development that can reduce the overall work process and time when constructing a cooling tower structure at the site and improve the precision and efficiency of the construction work.

The embodiment of the present invention is effective in reducing construction costs by reducing raw materials and shortening the construction period by forming the cooling tower structure in a block shape, and forming a lightweight strength-reinforced block structure without fear of corrosion, enabling faster and safer block assembly. It is to provide a CFRP block modular type cooling tower that can prevent safety accidents by reducing the risk of work at height and the risk of fire in the field.

CFRP block modular cooling tower according to an embodiment of the present invention is a block cell in the shape of a square frame structure formed of a carbon fiber reinforced plastic (CFRP) material, a block module formed by combining at least one or more block cells along a planar direction, and It includes a module unit in which block modules have different shapes and are selectively separated and coupled to each other along a height direction to form a plurality of layers in a preset stacked arrangement structure to support a corresponding cooling device.

In the module unit, four first block modules having first block cells individually form the bottom layer of the module unit, and the first block modules are arranged at intervals from each other so as to correspond to the bottom corner of the module unit, A first module unit forming a cooling passage for guiding the flow of cooling air in an upward direction, and a plurality of second block modules in which at least two second block cells are coupled above the first module unit are provided to form a module unit. A second module unit forming an intermediate layer of a cooling medium and forming a heat exchange space for a cooling medium, and a plurality of third block modules in which at least two or more third block cells are coupled above the second module unit are provided to form a plurality of module units. A third module unit forming an upper layer and supporting a cooling device may be included.

The first block cell is formed in a rectangular shape and is spaced apart from each other in the height direction at the pillar of the first block cell to form a frame in the height direction of the first block cell, and a first post member spaced apart from each other. A first beam member coupled to the first post member in the planar direction between the first beam member and forming a frame in the planar direction of the first block cell, and coupled to the first post member in the diagonal direction between the first post member and the first block cell It may include a first reinforcing member forming a reinforcing frame in the height direction. Here, a first connection member coupled to the upper and lower connection portions of the first block cell to integrally connect the first block cell to another structure may be further included.

The second block cell is formed long in the shape of a rectangular beam and is spaced apart from each other in the height direction at the pillar of the second block cell to form a frame in the height direction of the second block cell, and a second post member spaced apart from each other. The second beam member is coupled to the second post member in the planar direction between the second beam member to form the planar frame of the second block cell, and the second block cell is coupled to the second post member in the diagonal direction between the second post members It may include a second reinforcing member forming a reinforcing frame in the height direction. Here, a second connection member coupled to the upper and lower connection portions of the second block cell to integrally connect the second block cell to another structure may be further included. A plurality of second block cells may be arranged and combined in a horizontal direction or a vertical direction based on a planar direction.

The third block cell is formed long in the shape of a rectangular beam and is spaced apart from each other in the height direction at the pillar of the third block cell to form a frame in the height direction of the third block cell, and a third post member spaced apart from each other. A third beam member coupled to the third post member in the planar direction between the third beam member forming a planar frame of the third block cell, and coupled to the third post member in the diagonal direction between the third post member and the third block cell It may include a third reinforcing member forming a reinforcing frame in the height direction. Here, it may further include a third connection member that is coupled to the lower connection portion of the third block cell and integrally connects the third block cell to another structure. A plurality of third block cells may be arranged and combined in a horizontal direction or a vertical direction based on a planar direction.

The first block cell, the second block cell, and the third block cell may be formed of a CFRP material, and the first connection member, the second connection member, and the third connection member may be formed of a steel material.

The basic structure that forms the cooling tower is formed in a block-type structure made of carbon fiber reinforced plastic (CFRP), so there is no risk of corrosion, it is fire-resistant, it is lightweight, and the strength reinforcement can be maintained stably. It reduces the risk of safety accidents by minimizing work at height and selectively adjusts the arrangement structure to form a cooling passage for cooling air, which has the effect of improving cooling efficiency, saving raw materials, reducing construction costs, and shortening the overall construction period. .

1 is a view showing a state in which a CFRP block module type cooling tower according to an embodiment of the present invention is installed on the upper side of a water tank.
2 is a view showing a state in which a CFRP block module type cooling tower according to an embodiment of the present invention is arranged in the form of a three-stage module unit.
3 is a diagram showing a disposition relationship of first module units according to an embodiment of the present invention.
4 is a view showing a part of a second module unit according to an embodiment of the present invention.
5 is a view showing a part of a third module unit according to an embodiment of the present invention.
6 is a view showing a state in which module units according to an embodiment of the present invention are disposed and coupled in the form of a third module unit.

The terminology used herein is intended only to refer to specific embodiments and is not intended to limit the present invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of "comprising" specifies specific characteristics, regions, integers, steps, operations, elements, and/or components, and other specific characteristics, regions, integers, steps, operations, elements, elements, and/or groups. does not exclude the presence or addition of

Although not defined differently, all terms including technical terms and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Terms defined in commonly used dictionaries are additionally interpreted as having meanings consistent with related technical literature and currently disclosed content, and are not interpreted in ideal or very formal meanings unless defined.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a view showing a state in which a CFRP block module type cooling tower according to an embodiment of the present invention is installed on the upper side of a water tank, and FIG. 2 is a view showing a CFRP block module type cooling tower according to an embodiment of the present invention arranged in the form of a third module unit. This is a diagram showing the condition. And Figure 3 is a view showing the arrangement relationship of the first module unit according to an embodiment of the present invention, Figure 4 is a view showing a part of the second module unit according to an embodiment of the present invention, Figure 5 is a view showing this It is a view showing a part of the third module unit according to an embodiment of the invention. 6 is a view showing a state in which module units according to an embodiment of the present invention are disposed and coupled in the form of a third module unit. 1 to 6, the CFRP block modular cooling tower according to an embodiment of the present invention is a block cell formed of a square frame structure made of CFRP material, and a block formed by combining at least one or more block cells along a planar direction. It includes a module unit 100 in which a module and a block module have different shapes and are selectively separated and coupled to each other along a height direction to form a plurality of layers in a preset stacked arrangement structure to support a corresponding cooling device. Here, the CFRP material includes a plastic composite material using carbon fiber (CF) as a reinforcing material, and includes carbon fiber reinforced plastics. By using CFRP material to form a CFRP block modular cooling tower, the disadvantages of existing FRP and steel can be supplemented. In addition, it is possible to reduce the safety accident rate by maximizing ground work and minimizing work at height in the field. On the other hand, steel cooling towers are concerned about corrosion of steel materials because constant contact with water is inevitable due to the nature of the cooling tower structure. In addition, the strength of the material is low to form a block during the installation work of FRP general structures, so it is not suitable for block formation, and there is a risk of safety accidents due to work at high places in many sites. In the case of a general steel cooling tower, each module is overlapped 1:1, so materials are doubled in the overlapping part of the module, which can cause cost loss and lengthen the construction period. For example, in the case of a steel cooling tower, operational losses may occur due to overdesign and increased material costs due to increased materials and the burden of the customer and the construction period. In addition, as the material increases inside the steel cooling tower structure, the cooling efficiency may decrease due to the decrease in air flow.

Due to the nature of CFRP material, there is no risk of corrosion, and it is light in weight compared to steel, reducing construction cost and manpower. workload can be reduced. Therefore, by forming the module unit 100 in a structure suitable for the application of block modularization in which the middle can be omitted in a block type by utilizing CFRP material that has no possibility of corrosion and can maintain strength compared to light weight, raw materials and construction costs are reduced. The overall construction period can be shortened as it can reduce work at height in the site. In other words, the CFRP block module type cooling tower made of CFRP can be easily applied to block modularization inside and outside the site, and can be transported by truck and lifted immediately upon arrival on site, so the construction period can be shortened. Therefore, when designing the CFRP block modular cooling tower according to the embodiment of the present invention, the cooling tower structure supporting the installation of the heat exchange space and facility means on the foundation floor is formed in a divided structure according to the spatial arrangement, thereby reducing existing costs and manpower. It is possible to realize the stability of the cooling tower structure without much difference from

The module unit 100 may include a first module unit 110 , a second module unit 120 , and a third module unit 130 . First, the first module unit 110 is provided on the upper side of the water tank 10 in which the cooling water 12 is stored, and may be provided on the upper side of the water tank 10 in a spaced apart arrangement structure. In the first module unit 110, four first block modules each having first block cells form a bottom layer of the module unit 100, and the first block module is a corner portion of the bottom surface of the module unit 100. It is possible to form a cooling passage for guiding a flow of cooling air from the bottom to the top by being disposed at intervals from each other so as to correspond to the above. The first block cell is formed long in the shape of a rectangular beam and is spaced apart from each other in the height direction at the pillar of the first block cell to form a frame in the height direction of the first block cell. Between the post members 112, the first beam member 114 coupled to the first post member 112 in the planar direction to form the frame in the planar direction of the first block cell, and the first post member 112 It may include a first reinforcing member 116 coupled to the first post member 112 in a diagonal direction to form a reinforcing frame in the height direction of the first block cell. A first connection member 118 coupled to upper and lower connection portions of the first block cell to integrally connect the first block cell to another structure may be further included.

As described above, in the first block cell forming the first module unit 110, the first post member 112 is coupled in the vertical direction and the first beam member 114 is coupled in the horizontal direction using bolts. can be fixed The first reinforcing members 116 may be coupled in an X-shape or oblique (/) shape along a diagonal direction in post members corresponding to each other. As described above, one first block cell is formed using the first post member 112, the first beam member 114, and the first reinforcing member 116, and using the first connecting member 118 It can be combined with the lower water tank 10 or the upper second module unit 120. The first connecting member 118 includes an upper bracket or a lower anchor plate, and may be coupled to other structures through bolts. Meanwhile, the first post member 112 is formed with an extra length in order to increase workability at the site, and the extension length of the first post member 112 may be properly cut and installed at the site. Therefore, workability can be increased by cutting the extended length of the first post member 112 at the time of on-site installation. For example, the extended length of the first post member 112 may be formed as a site-customized level adjustment structure. The extended length of the first post member 112 can be properly cut even if there is an error in the level of the water tank or pedestal at the site, thereby enabling site-customized block installation. When there is no extended length of the first post member 112, it is possible to customize the site by adding a plate with a minus (-) tolerance at a specific post point. However, when a specific post point has a plus (+) tolerance, it is difficult to install because the level of all blocks is changed. The first post member 112 according to the embodiment of the present invention is formed with an extended length, so that site-customized cutting is possible when adjusting the level of the block, so that the site-customized block can be easily installed without distinction of plus tolerance or minus tolerance.

In the first module unit 110, the first block cells may independently form each first block module. For example, assuming that one first module unit 110 is formed in a space where a total of nine first block cells can be arranged, four A block cell may form a first block module. In addition, the space in which the five first block modules can be disposed in the middle may be maintained as an empty space and used as a passage for cooling air. As described above, by arranging four first block modules in a space where a total of nine first block modules are to be placed, and forming an empty space in the middle of five first block module placement spaces, the first block modules are spaced apart from each other. condition can be maintained, unnecessary interference can be minimized when the cooling air is introduced, and the flow of the cooling air can be introduced more reliably and stably. In addition, by reducing the overlapping portion of the first block module, it is possible to reduce the cost and weight of the post member, the beam member, and the double reinforcing member, and shorten the installation period.

The second module unit 120 is coupled to the upper side of the first module unit 110, forms a space into which a filler for heat exchange between water and air is inserted, and supports the filler. The second module unit 120 is provided with a nozzle for spraying hot water downward through an upper pipe (header pipe, lateral pipe) and supports a function of cooling by heat exchange through a filler. The second module unit 120 is provided with a plurality of second block modules in which at least two or more second block cells are coupled on the upper side of the first module unit 110 to form an intermediate layer of the module unit 100, cooling A medium heat exchange space can be formed. The second block cell is formed in a rectangular shape and is spaced apart from each other in the height direction at the pillar of the second block cell to form a frame in the height direction of the second block cell. Between the post members 122, the second beam member 124 coupled to the second post member 122 in the planar direction to form the frame in the planar direction of the second block cell, and the second post member 122 It may include a second reinforcing member 126 coupled to the second post member 122 in a diagonal direction to form a reinforcing frame in the height direction of the second block cell. A second connection member 128 coupled to upper and lower connection portions of the second block cell and integrally connecting the second block cell to another structure may be further included. As described above, the second block cell forming the second module unit 120 is one second block cell using the second post member 122, the second beam member 124, and the second reinforcing member 126. A block cell is formed, and a corresponding second block module unit may be formed by a combination of the second block cells. The second post member 122 is coupled in the vertical direction, the second beam member 124 is coupled in the horizontal direction can be fixed using bolts. The second reinforcing members 126 may be coupled in the shape of an X or a diagonal line (/) along a diagonal direction in post members corresponding to each other. The second connection member 128 may be provided in the form of a bracket at the top and bottom of the second module unit 120 , respectively. It can be combined with the third module unit 130 using the second connecting member 128 at the top and coupled with the first module unit 110 using the second connecting member 128 at the bottom.

A plurality of second block cells may be arranged and combined in a horizontal direction or a vertical direction based on a planar direction. The second module unit 120 may be formed in a form in which three second block modules are coupled. For example, when a total of 9 second block cells form one second module unit 120, 3 block cells are combined in 1 column, 1 3-cell block module in 1 column, and 2 block cells are 2 One 2-column 4-cell block module combined in a row and one 1-column 2-cell block module in which two block cells are combined in a row may be formed.

The third module unit 130 is coupled to the upper side of the second module unit 120 and supports the cooling device. Here, the cooling device may include a cooling fan, a motor, and the like for discharging air to the outside, and may include mechanical parts including a power transmission device. The third module unit 130 functions to prevent scattering by installing an eliminator, and supports workers to pass at the top of the cooling tower by installing a deck panel and a handrail. Can include scaffolding function. The third module unit 130 is provided with a plurality of third block modules in which at least two or more third block cells are coupled on the upper side of the second module unit 120 to form an upper layer of the module unit 100, and is cooled. It may include a third module unit 130 supporting the device. The third block cell is formed in a rectangular shape and is spaced apart from each other in the height direction at the pillar of the third block cell to form a frame in the height direction of the third block cell. Between the third beam member 134 coupled to the third post member 132 in the planar direction between the post members 132 to form the frame in the planar direction of the third block cell, and the third post member 132 It may include a third reinforcing member 136 coupled to the third post member 132 in a diagonal direction to form a reinforcing frame in the height direction of the third block cell. The third post member 132 also has a general structure post or a post structure that simultaneously functions as a structure and a handrail. A third connection member 138 coupled to a lower connection portion of the third block cell and integrally connecting the third block cell to another structure may be further included. As described above, the third block cell forming the third module unit 130 is one third block cell using the third post member 132, the third beam member 134, and the third reinforcing member 136. A block cell is formed, and a corresponding third block module unit may be formed by a combination of the third block cells. The third post member 132 is coupled in a vertical direction, and the third beam member 134 is coupled in a horizontal direction and may be fixed using bolts. The third reinforcing member 136 may be coupled in an X-shape or diagonal (/) shape along a diagonal direction in post members corresponding to each other. The third reinforcing member 136 may be applied in an X-shape or oblique (/) shape based on a corresponding structural calculation according to an installation location. The third reinforcing member 136 may be installed in an X shape in a diagonal direction to post members corresponding to each other in the height direction of the square frame structure forming the third block cell. The third reinforcing member 136 may be installed on all four virtual planes in the height direction in the third block cell, and may be selectively installed as needed. As the third reinforcing member 136 is installed, even if an external force such as wind or vibration is transmitted to the third block cell having a rectangular frame structure, it is possible to increase stability by reinforcing the supporting force of the third block cell. The third connection member 138 may be provided in the form of a bracket under the third module unit 130 . The third module unit 130 and the second module unit 120 may be coupled using the third connection member 138 .

A plurality of third block cells may be arranged and combined in a horizontal direction or a vertical direction based on a planar direction. The third module unit 130 may be formed in a form in which three third block modules are coupled. For example, when a total of nine third block cells form one third module unit 130, one row three-cell block module in which three block cells are combined in one row and two block cells are two One 2-column 4-cell block module combined in a row and one 1-column 2-cell block module in which two block cells are combined in a row may be formed. As described above, the third module unit 130 and the second module unit 120 may have the number of block cells disposed to correspond to each other. Meanwhile, the third module unit 130 may separately form a portion where a cooling fan is installed on the top.

The first block cell, the second block cell, and the third block cell are formed of a CFRP material, and the first connection member 118, the second connection member 128, and the third connection member 138 are formed of a steel material. can The first connection member 118, the second connection member 128, and the third connection member 138 each have fastening holes, and may be fastened with bolts. A magnetic material may be coupled to the first connecting member 118 , the second connecting member 128 , and the third connecting member 138 as needed. For example, the first connecting member 118, the second connecting member 128, and the third connecting member 138 are basically formed of a steel material, and a magnetic material is coupled to some of them to primarily combine the steel and the magnet. And, secondarily, by fastening the connecting members corresponding to each other with bolts, it is possible to maintain a faster and more robust coupling relationship. Meanwhile, when a plurality of block cells or a plurality of block modules are coupled, a connection member may be coupled to a connection portion of each block cell or block module. The connecting member may be formed in a corresponding shape depending on the location where it is installed. The connecting member may be formed as an integral structure coupled to either side of block cells or block modules corresponding to each other. Here, the integrated structure of the connecting member refers to a structure capable of combining block cells or block modules corresponding to each other with one connecting member. On the other hand, the connecting member may also be formed as a separate coupling structure coupled to both sides of each block cell or block module corresponding to each other. Here, the separate coupling type structure of the connecting member refers to a structure capable of combining block cells or block modules corresponding to each other with a coupling structure of two connecting members corresponding to each other.

As described above, in the CFRP block modular type cooling tower according to an embodiment of the present invention, a square frame-shaped block cell formed by a combination structure of a post member, a beam member, and a reinforcing member forms a basic unit block in a block structure of a cooling tower structure. do. At least one fastening hole may be provided at each fastening part of the post member, the beam member, and the reinforcing member. The fastening hole is provided with a size into which the bolt is inserted, and when the post member and the beam member or the post member and the reinforcing member are coupled, matching the fastening holes corresponding to each other, and then fastening with the corresponding bolt and nut, the post member, the beam member, And a reinforcing member may be coupled. That is, the assembly of each block cell does not require separate welding and can be assembled in a bolted structure. In addition, the block cell installation work position ratio can reduce the risky construction situation in the field by distinguishing external block cell assembly and field installation. These block cells may be formed in the form of different block modules for each stage. For example, block cells may be arranged as individual block modules, or at least one or more block cells may be combined to form a block module in a block cell assembly form. In addition, the block module may be formed of a plurality of layers corresponding to the design of the cooling tower structure to form the final module unit 100 . A cooling fan and a motor are provided on the upper part of the multi-layered module unit 100 , and air may be introduced from the lower part to the upper part of the module unit 100 .

A method of constructing a CFRP block modular cooling tower according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6.

The CFRP block module type cooling tower is installed to support a cooling device provided at a position where a cooling medium passes along the height direction from the bottom surface. Here, the cooling device includes a spraying device for injecting a cooling medium into the heat exchange space, a circulation device including a water tank 10 for storing the cooling medium at the lower part of the heat exchange space and a pump for circulating the cooling medium, and air in the heat exchange space to the outside. A blower may be included to discharge and circulate outside air into the cooling tower. In the CFRP block modular type cooling tower, workers can assemble various block cells and block modules to install the corresponding module unit 100 on scaffolding installed on the basis of the field survey data on the installation site. In this way, when the installation of the CFRP block module type cooling tower is completed, the installed scaffolding for internal movement is dismantled to complete the construction work.

First, a block cell in the shape of a rectangular parallelepiped outer frame and a block module in which at least one or more block cells are assembled are temporarily assembled in the field using a post member, a beam member, and a reinforcing member formed of CFRP. At this time, the post member and the beam member may be assembled by being fastened with bolts and nuts via a connecting member. Here, the block module may be formed in a plurality of different shapes according to the laminated structure. For example, it may include a first module unit 110 fixedly installed on the floor and a second module unit 120 installed above the first module unit 110 . Each of the first module unit 110 and the second module unit 120 may be formed by a combination of different block cells. If necessary, a third module unit 130 may be installed above the second module unit 120 .

The temporarily assembled first module unit 110 is moved to an installation position using a crane. Thereafter, the temporarily assembled second module unit 120 is moved from the upper side of the first module unit 110 to a position where it can be connected. The first module unit 110 and the second module unit 120 are assembled on both sides using bolts and nuts through a connecting member corresponding to the first module unit 110 and the second module unit 120. connect By repeating the above operation, the corresponding second module unit 120 and the third module unit 130 may be connected in a prefabricated manner to complete the cooling tower structure.

As described above, the CFRP block modular type cooling tower does not assemble and construct each component of the cooling tower at the work site, but by combining independent block cells or block modules by the number selected at the work site so that they can be fastened together at the manufacturing site, CFRP with the desired capacity A block modular type cooling tower can be constructed. Therefore, it is possible to promote the convenience of work at the work site. In addition, the CFRP block modular cooling tower can implement the module unit 100 through a combination of block modules formed in a divided structure according to the spatial arrangement, and by transporting and assembling to the foundation floor at the manufacturing site, securing the simplicity of construction and There are effects such as reducing raw materials, reducing construction costs, and shortening construction period.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims and the detailed description of the invention and the accompanying drawings, and this is also It goes without saying that it falls within the scope of the present invention.

10; water tank 12; cooling water
100; module unit 110; 1st module unit
112; 1st post member 114; 1st beam member
116; First reinforcing member 118; First connecting member
120; Second module unit 122; 2nd post member
124; Second beam member 126; 2nd reinforcing member
128; Second connecting member 130; 3rd module unit
132; Third post member 134; 3rd beam member
136; Third reinforcing member 138; 3rd connecting member

Claims (5)

A block cell in the shape of a square frame structure containing carbon fiber reinforced plastic (CFRP),
A block module formed by combining at least one block cell along a planar direction, and
A module unit in which the block modules are selectively separated from each other along the height direction to form a plurality of layers in a preset stacked arrangement structure to support the corresponding cooling device
A CFRP block modular cooling tower comprising a. In paragraph 1,
The module unit
A first block module equipped with a plurality of first block cells forms the bottom layer of the module unit with a site-customized level control structure, and the first block modules are spaced apart from each other so as to correspond to the corner of the bottom surface of the module unit. A first module unit disposed so as to form a cooling passage for guiding a flow of cooling air from the bottom to the top;
A second block module equipped with a plurality of second block cells above the first module unit forms an intermediate layer of the module unit and forms a heat exchange space for a cooling medium, and
A CFRP block module type cooling tower comprising a third module unit in which a third block module equipped with a plurality of third block cells forms an upper layer of the module unit on the upper side of the second module unit and supports a cooling device. In paragraph 2,
The first block cell is
A first post member that is formed in a rectangular shape and is spaced apart from each other in the height direction at the pillar of the first block cell to form a frame in the height direction of the first block cell;
A first beam member coupled to the first post member in a planar direction between the first post members spaced apart from each other to form a planar frame of the first block cell, and
A first reinforcing member coupled to the first post member in a diagonal direction between the first post members to form a reinforcing frame in the height direction of the first block cell.
A CFRP block modular cooling tower comprising a. In paragraph 3,
The CFRP block modular cooling tower further comprising a first connection member coupled to the upper and lower connection parts of the first block cell to integrally connect the first block cell to another structure. In paragraph 4,
The first block cell, the second block cell, and the third block cell are formed of a CFRP material, and the first connection member is formed of a steel material.

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