JPH06257965A - Cooling tower - Google Patents

Abstract

PURPOSE:To provide a cooling tower, having a high cooling efficiency and capable of being used in a place, limited in the height of the cooling tower. CONSTITUTION:A pair of first filler blocks 1 are provided at both sides of a ventilating space 15 and a second filler block 5 is arranged below the ventilating space 15 while a cooling fan 3 is provided above the ventilating space 15. A first spray nozzle 11 and a second spray nozzle 12, through which hot-water is supplied respectively, are provided above the first filler block 1 and the second filler block 5. Cross-flow system cooling, in which air stream passes horizontally with respect to the downflow hot water, is effected in the first filler blocks 1 while counter flow system cooling, in which air stream passes in a counter direction with respect to the downflow direction of the hot-water, is effected in the second filler block 5. Accordingly, a high cooling efficiency can be obtained by adopting both of the cross-flow system and counter-flow system. Further, the first filler blocks 1 and the second filler block 5 can utilize the ventilating space 15 commonly whereby the height of a cooling tower can be restrained so as to be low.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-layered cooling tower for cooling hot water discharged from factory facilities, building air conditioners and the like with high efficiency.

[0002]

2. Description of the Related Art Conventionally, cooling towers used to circulate hot water discharged from factory facilities, building heating and cooling devices, and the like include a cross-flow type and a counter-flow type. . FIG. 3 schematically shows a cross-sectional structure of a cross-flow type cooling tower which has been conventionally used.
As shown in the figure, in the cross flow system, the ventilation space 25
Fillers 20, 20 are installed on both sides of, and a cooling fan 23 is attached above the ventilation space 25. Hot water is supplied from above the fillers 20 by the water spray nozzles 21, and the supplied hot water flows down through the fillers 20.

On the other hand, the suction of the cooling fan 23 causes the filler 2 to flow from the louver 22 provided on the side of the filler 20.
An air flow is generated in the ventilation space 25 via 0, and the hot water flowing down in the filler 20 is cooled by this air flow. As described above, in the cross-flow type cooling tower, the airflow is supplied from the lateral direction to the hot water flowing down. Filling material 2
The water that has passed through 0 becomes cold water and is received by the cold water tank 24. The ventilation space 25 is provided to collect and raise the air after heat exchange from the upper portion to the lower portion of the filling material 20.

FIG. 4 schematically shows a cross-sectional structure of a conventional counterflow type cooling tower. As shown in the figure, in the counter flow system, hot water is supplied from the water spray nozzle 21 in the ventilation space 25 above the packing material 20 installed almost horizontally in the tower, and while flowing down through the packing material 20. , Is cooled by coming into contact with the airflow by the suction of the cooling fan 23. As described above, in the counter flow type cooling tower, the air flow is supplied from the direction opposite to the flowing hot water. In the counter flow type cooling tower, a ventilation space of a certain size is provided in order to provide a pipe for supplying hot water to the sprinkling nozzle 21 and to generate a uniform air flow over the entire surface of the filler 20. 25 is required.

However, in the conventional cooling towers using these methods, the cooling efficiency may be insufficient. In order to improve the cooling efficiency, cooling towers known from JP-A-63-36850 and JP-B-46-7460 are known. An example of this type of cooling tower is shown in FIG. The cooling tower shown in the figure performs cooling by a cross flow method.
It has a pair of filler blocks 30 and 31. That is,
Sprinkling nozzles 33 and 34 are provided separately for the upper pair of filler blocks 30 and the lower pair of filler blocks 31, respectively, and the cooling water from the upper filler block 30 is It is guided to the drainage tank 36 by the drainage pipe 35 without passing through the filling material block 31.

[0006]

However, in the cooling tower of FIG. 5, since the filler blocks 30 and 31 are provided in two stages, the ventilation space is also twice as high, and the height of the entire tower is high. I will end up. Therefore, there is a problem that this cooling tower cannot be installed in a place where height is restricted.

The present invention solves such a problem, and an object of the present invention is to provide a cooling tower which has a high cooling efficiency and can be used even in a place where the height is limited. Is.

[0008]

A cooling tower according to the first invention of the present application comprises: a first packing material block facing each other with a ventilation space interposed therebetween; and a second packing material block arranged below the ventilation space. A cooling fan provided above the ventilation space, a first hot water supply means for supplying hot water to each of the first packing blocks, and a second hot water supply means for supplying hot water to the second packing blocks. And a cold water tank for storing cold water flowing down from the first and second filling material blocks, and the hot water flowing down in the first filling material block is sucked by a cooling fan through the ventilation space. The hot water that is cooled by the air flow in the cross flow method and that flows down in the second filler block is cooled by the counter flow method by the air flow sucked by the cooling fan through the ventilation space. That.

In addition, an auxiliary cooling fan can be further added directly above the second filler block in the ventilation space.

Further, the cooling tower according to the second invention of the present application is provided with a filler block facing each other across the ventilation space, a cooling space disposed below the ventilation space, and above the ventilation space. A cooling fan, a first hot water supply means for supplying hot water to each of the filler blocks, a second hot water supply means for supplying warm water to the cooling space, and a cold water flowing down from the filler block and the cooling space. With a cold water tank to store, the hot water flowing down in the filler block is cooled in a cross-flow method by the airflow sucked by a cooling fan through the ventilation space, the hot water supplied to the cooling space is, It is characterized in that it is cooled by a counterflow method by an airflow sucked by a cooling fan through the ventilation space.

[0011]

In the cooling tower having the above structure, the hot water is cooled in the first packing material block facing the ventilation space and the second packing material block arranged below the ventilation space. Cross flow type cooling is performed in the first filler block. That is, the hot water supplied from the first hot water supply means is cooled by the air flow from the side that is sucked through the ventilation space by the cooling fan while flowing down in the first filler block. Further, in the second filling material block, counter flow type cooling is performed. That is,
The hot water supplied from the second hot water supply means is cooled by the air flow from below that is sucked through the ventilation space by the cooling fan while flowing down in the second filler block. With this configuration, since the ventilation space can be shared by the first filler block that performs the cross-flow cooling and the second filler block that performs the counter-flow cooling, the height of the cooling tower can be kept low. Meanwhile, the cooling efficiency can be improved.

Further, by providing an auxiliary cooling fan directly above the second filler block in the ventilation space, it is possible to compensate for the insufficient capacity of the cooling fan due to the increase of the filler. Further, when the amount of air flow with respect to the amount of warm water in the second filler block is smaller than the amount of air flow with respect to the amount of warm water in the first filler block, the auxiliary cooling fan causes the second filler block to flow. The balance of the airflow can be adjusted by increasing the amount of airflow passing through.

Further, in the above structure, the second filling material block is not used, and the hot water supplied from the second hot water supply means is used as a cooling space which is cooled only by the air flow. A cooling tower with high cooling efficiency can be constructed.

[0014]

Embodiments of the present invention will now be described in more detail with reference to the drawings.

FIG. 1 shows a schematic sectional structure of a cooling tower according to a first embodiment of the present invention. The cooling tower of the present embodiment has a pair of first filler blocks 1 facing each other with the ventilation space 15 interposed therebetween.
And the second filler block 5 arranged below the ventilation space 15. A cooling fan 3 is provided above the ventilation space 15.

A hot water tank 13b is provided above each first filler block 1, and hot water is supplied to the hot water tank 13b from a hot water supply pipe 18 via a sprinkler box 13a. Also,
A first water spray nozzle 11 is attached to each hot water tank 13 b, and hot water is supplied to the first filler block 1 by the first water spray nozzle 11. In the present embodiment, the hot water supply pipe 18, the water sprinkling box 13a, the hot water tank 13b, and the first water sprinkling nozzle 11 constitute a first hot water supply means. An eliminator 8 is provided on the ventilation space 15 side of each first filler block 1 in order to prevent fine water droplets from being discharged to the outside through the ventilation space 15.

Similarly, above the second filler block,
A water spray pipe (spray device) 14 is provided, and hot water is directly supplied to the water spray pipe 14 from a hot water supply pipe 19. A second water spray nozzle 12 is attached to the water spray pipe 14, and hot water is sprayed onto the second filler block 5 by the second water spray nozzle 12. In this embodiment, the water supply pipe 19, the water spray pipe 14, and the second water spray nozzle 12 constitute a second hot water supply means. Also, the second
An eliminator 9 is provided between the filler block 5 and the ventilation space 15.

A louver 2 is provided outside each of the first filler block 1 and the second first filler block 5,
From these louvers 2 to the first filler block 1 and the second filler block 1
An airflow that passes through the filler block 5 and reaches the ventilation space 15 is generated by the suction of the cooling fan 3.

Below each of the first filler blocks 1, there is provided a pair of water receiving tanks 6 for receiving cold water flowing down from the first filler blocks 1. Further, the cold water accumulated in these water receiving tanks 6 is stored in the cold water tank 4 via the drain pipe 7. Further, the cold water flowing down from the second filler block 5 is also stored in the cold water tank 4.

The first filler block 1 is cooled by a cross flow method. Specifically, the hot water flowing down in the first filler block 1 is cooled by the airflow that passes through the first filler block 1 from the louver 2 and reaches the ventilation space 15. That is, the air flow in the first filling material block 1 deprives the heat of vaporization from the lateral direction with respect to the hot water flowing down in the first filling material block 1.

On the other hand, the second filling material block 5 is cooled by the counter flow method. Specifically, the second
The hot water flowing down in the filler block 5 is cooled by an airflow that passes through the second filler block 5 from below the second filler block 5 and reaches the ventilation space 15. That is, the air flow in the second filling material block 5 is
The heat of vaporization will be taken from the direction facing the hot water flowing down the inside.

In this embodiment, since the first filler block 1 for cooling in the cross flow system and the second filler block 5 for cooling in the counter flow system are provided, high cooling efficiency can be obtained. Moreover, since the ventilation space 15 is shared by the first packing block 1 and the second packing block 5, it is possible to suppress an increase in the height of the tower due to the improvement in cooling efficiency.

In this embodiment, when the capacity of the cooling fan 3 becomes insufficient due to the increase of the filling material, the second filling in the ventilation space 15 is performed as shown by the chain double-dashed line in FIG. This can be supplemented by further providing the auxiliary cooling fan 16 directly above the material block 5. In addition, when the amount of airflow with respect to the amount of hot water in the second filling material block 5 is smaller than the amount of airflow with respect to the amount of warm water in the first filling material block 1, the second cooling is performed by the auxiliary cooling fan 16. The balance of the airflow can be adjusted by increasing the amount of the airflow passing through the material block 5.

FIG. 2 shows a schematic sectional structure of a cold water tower according to a second embodiment of the present invention. In the cold water tower of this embodiment, the cooling space 17 is simply used without using the second filler block 5 in the structure of the first embodiment. The rest of the configuration is the same as that of the embodiment of FIG. 1, and corresponding parts are designated by the same reference numerals. In the cooling tower of this embodiment, the warm water supplied from the second water spray nozzle 12 is cooled by the air flow supplied from the louver 2 while falling in the cooling space 17. Therefore, even in the cooling space 17, cooling by the counter flow method is performed. By thus providing the cooling space 17 without a filler, it is possible to configure a cooling tower that is inexpensive and has a relatively high cooling efficiency.

FIG. 6 schematically shows the sectional structure of a cold water tower according to the third embodiment of the present invention. The cold water tower of the present embodiment is one in which the volume of the cooling tower in the above-mentioned first embodiment is further reduced. That is, the space between the first filler block 1 and the second filler block 5 is eliminated, and only the partition plate 40 is provided between these filler blocks 1 and 5.
Further, an openable / closable damper 42a is provided in place of the louver 2 in the portion corresponding to the first filler block 1 in FIG. 1, and the louver 2 in the portion corresponding to the second filler block 5 is provided.
Instead, a damper 42b that can be opened and closed is provided.
The rest of the configuration is the same as that of the embodiment of FIG. 1, and corresponding parts are designated by the same reference numerals.

In the cold water tower of this embodiment, the ventilation operation according to the required cooling capacity can be performed by opening / closing the dampers 42a and 42b. That is, when high cooling efficiency is required, such as in a summer air conditioner, the dampers 42a and 42b are
When both of the dampers 42a and 42b are released and only a low cooling efficiency is required when the cooling fan 3 is operated by increasing the blowing capacity of the cooling fan 3, the blowing fan of the cooling fan 3 is released. Energy-saving operation becomes possible by lowering the capacity.

In the above-mentioned first and second embodiments,
I explained about the cooling tower whose overall shape is an inverted trapezoid,
Needless to say, the shape is not limited to this, and may be a rectangular shape as shown in FIG.

[0028]

The chilled water tower according to the present invention is provided with the first filler block for cooling in the cross-flow system and the second filler block for cooling in the counter-flow system, so that high cooling efficiency is achieved. Obtainable. Moreover,
Since the ventilation space is shared by the above two methods, it is possible to suppress the increase in the height of the cooling tower due to the improvement in cooling efficiency as much as possible. Therefore, the cooling tower of the present invention can be installed even in a place where the height is severely restricted, and high cooling efficiency can be exhibited.

[Brief description of drawings]

FIG. 1 is a sectional view showing a schematic configuration of a cooling tower according to a first embodiment of the present invention.

FIG. 2 is a sectional view showing a schematic configuration of a cooling tower according to a second embodiment of the present invention.

FIG. 3 is a cross-sectional view showing a schematic configuration of a conventional cross-flow type cooling tower.

FIG. 4 is a cross-sectional view showing a schematic configuration of a conventional counter flow type cooling tower.

FIG. 5 is a cross-sectional view showing a schematic configuration of a cooling tower in which a conventional cross-flow type packing material is formed in two stages.

FIG. 6 is a sectional view showing a schematic configuration of a cooling tower according to a third embodiment of the present invention.

[Explanation of symbols]

 1 ... 1st filler block 2 ... Louver 3 ... Cooling fan 4 ... Cold water tank 5 ... 2nd filler block 8 ... Eliminator 9 ... Eliminator 11 ... 1st water spray nozzle 12 ... 2nd water spray nozzle 15 ... Ventilation space 16 ... Auxiliary Cooling fan 17 ... Cooling space

Claims (3)

[Claims] 1. A first filler block facing each other across a ventilation space, a second filler block arranged below the ventilation space, a cooling fan provided above the ventilation space, and First hot water supply means for supplying hot water to the first filling material block, second hot water supply means for supplying hot water to the second filling material block, and flow down from the first and second filling material blocks. A cold water tank for storing cold water, wherein the hot water flowing down through the first filler block is cooled in a cross-flow method by an airflow sucked by a cooling fan through the ventilation space, and the second filler block A cooling tower characterized in that hot water flowing down is cooled by a counterflow method by an airflow sucked by a cooling fan through the ventilation space. 2. The cooling tower according to claim 1, further comprising an auxiliary cooling fan directly above the second filler block in the ventilation space. 3. A filling material block facing each other across the ventilation space, a cooling space arranged below the ventilation space, a cooling fan provided above the ventilation space, and hot water for each of the filling material blocks. A first hot water supply means for supplying the hot water, a second hot water supply means for supplying the hot water to the cooling space, and a cold water tank for storing cold water flowing down from the filling material block and the cooling space. The hot water flowing down in the block is cooled in a cross-flow method by the air flow sucked by the cooling fan through the ventilation space, and the hot water supplied to the cooling space is sucked by the cooling fan through the ventilation space. A cooling tower characterized in that it is cooled by a counter flow method by an air flow.