KR20230139500A - Cooling tower - Google Patents

Abstract

Embodiments of the present invention provide a cooling tower that facilitates power generation using cooling water during operation of the cooling tower. According to one embodiment of the present invention, disclosed is a cooling tower including: a water supply unit arranged to supply cooling water to be heat exchanged with air introduced from the outside; a heat exchange area disposed in an area overlapping with the cooling water supplied through the water supply unit; a water collection area where the cooling water heat exchanged in the heat exchange area is collected; and a power generation member disposed between the heat exchange area and the water collection area based on the direction of gravity and moving by the heat exchanged cooling water to generate electrical energy.

Description

Cooling tower

Embodiments of the present invention relate to cooling towers.

With the advancement of technology, coolants are being used in various fields. For example, coolant is used in air conditioning equipment, refrigeration equipment, and other fields, and the used coolant is heated.

Various devices are used to reduce the temperature by cooling the heated cooling water again, and a cooling tower is used as a specific example.

There are limits to the efficient operation of the cooling tower depending on the conditions and timing of use of the cooling tower.

Embodiments of the present invention provide a cooling tower that can easily generate power using cooling water when operating the cooling tower.

One embodiment of the present invention includes a water supply unit arranged to supply cooling water to be heat-exchanged with air introduced from the outside, a heat exchange area disposed in an area overlapping with the coolant supplied through the water supply unit, and a heat exchange area where the coolant heat-exchanged in the heat exchange area is collected. Disclosed is a cooling tower including a power generation member disposed between the heat exchange area and the water collection area based on the water collection area and the direction of gravity, and generating electrical energy by moving by the heat exchanged cooling water.

Another embodiment of the present invention includes a water supply unit arranged to supply cooling water to be heat-exchanged with air introduced from the outside, a heat exchange area disposed in an area overlapping with the coolant supplied through the water supply unit, and a heat exchange area where the coolant heat-exchanged in the heat exchange area is collected. a water collection area, a coolant coil part formed to exchange heat with the outside air and allow coolant to move to the water supply part, and a coolant coil part formed between the coolant coil part and the water supply part based on the direction of gravity to move by the coolant to generate electrical energy. Disclosed is a cooling tower including a power generation member that:

In this embodiment, the power generating member may include a moving member configured to rotate by the cooling water.

In this embodiment, the power generating member may include a control unit that converts the kinetic force generated by the coolant into electrical energy or performs signal processing therefor.

In this embodiment, the power generating member may include one disposed to overlap the heat exchange area or the water collection area.

Other aspects, features and advantages in addition to those described above will become apparent from the following drawings, claims and detailed description of the invention.

The cooling tower according to this embodiment can easily generate power using cooling water when operating the cooling tower.

1 is a diagram schematically showing a cooling tower according to an embodiment of the present invention.
FIG. 2 is a schematic diagram of a cooling tower according to an alternative embodiment of the cooling tower of FIG. 1.
Figure 3 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 4 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 5a is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
FIGS. 5B to 5D are diagrams for explaining various modifications of FIG. 5A.
Figure 6 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 7 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 8 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 9 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.
Figure 10 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. When describing with reference to the drawings, identical or corresponding components will be assigned the same reference numerals and redundant description thereof will be omitted. .

In the following embodiments, terms such as first and second are used not in a limiting sense but for the purpose of distinguishing one component from another component.

In the following examples, singular terms include plural terms unless the context clearly dictates otherwise.

In the following embodiments, terms such as include or have mean that the features or components described in the specification exist, and do not exclude in advance the possibility of adding one or more other features or components.

In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the size and thickness of each component shown in the drawings are shown arbitrarily for convenience of explanation, so the present invention is not necessarily limited to what is shown.

In the following embodiments, the x-axis, y-axis, and z-axis are not limited to the three axes in the Cartesian coordinate system, but can be interpreted in a broad sense including these. For example, the x-axis, y-axis, and z-axis may be orthogonal to each other, but may also refer to different directions that are not orthogonal to each other.

In cases where an embodiment can be implemented differently, a specific process sequence may be performed differently from the described sequence. For example, two processes described in succession may be performed substantially at the same time, or may be performed in an order opposite to that in which they are described.

1 is a diagram schematically showing a cooling tower according to an embodiment of the present invention.

Referring to FIG. 1 , the cooling tower 100 may include a water supply unit 110, a heat exchange area 120, a water collection area 150, and a power generation member 130.

The water supply unit 110 may be arranged to supply cooling water to exchange heat with air introduced from the outside.

Although not shown, the cooling tower 100 of this embodiment may have various shapes, and as an example, it includes a housing (not shown), and at least one area of the water supply unit 110 is disposed inside the housing (not shown). Cooling water can be supplied.

The water supply unit 110 may have various forms, and as an example, may include one or more pipe shapes having an area through which cooling water supplied from the outside passes, and may have a structure in which a plurality of nozzles connected to these pipe shapes are formed. You can.

The water supply unit 110 may be formed to supply cooling water downward, for example, in the direction of gravity (G).

Although not shown, the cooling tower 100 may include one or more intake areas (not shown) formed to allow external air to flow in, for example, into the inside of the housing (not shown). As a specific example, one or more intake areas (not shown) may be formed lower than the water supply unit 110 based on the direction of gravity (G).

Although not shown, an exhaust area (not shown) may be formed in one area of the cooling tower 100, for example, one side, or at least one area on the upper side as a specific example. The “upper side” is an area opposite to the direction of gravity (G), and as an optional embodiment, an exhaust area (not shown) may be formed on the upper side of the water supply unit 110.

Heated gas used in coolant heat exchange or other residual gas may be discharged to the outside through this exhaust area (not shown). Additionally, as an optional embodiment, one or more blowing members may be further disposed to correspond to this exhaust area (not shown).

The heat exchange area 120 may be disposed in an area where the cooling water supplied through the water supply unit 110 overlaps.

For example, the heat exchange area 120 may be disposed lower than the water supply unit 110 based on the direction of gravity (G).

Cooling water supplied (for example, sprayed) through the water supply unit 110 may undergo a heat exchange process in the heat exchange area 120, and, as an example, may undergo a heat exchange process with air introduced from the outside.

The heat exchange area 120 may have various forms, for example, may be formed to include a filling member that fills the inner space of the housing (not shown), and the surface or plurality of filling members of the heat exchange area 120 may be formed. In the space between the filling members, the heat exchange process may proceed as the coolant flows in the direction of gravity (G) and the air moves in the opposite direction.

The water collection area 150 may include an area where the coolant heat-exchanged in the heat exchange area 120 is collected. As an example, the water collection area 150 may be placed lower than the heat exchange area 120 based on the direction of gravity (G).

The coolant whose temperature has been lowered through the heat exchange process in the heat exchange area 120 may be moved to one area, for example, in the direction of gravity action (G), and as a specific example, may be moved naturally to the water collection area 150 by gravity. You can. Through this, the cooling water whose temperature has been lowered can be smoothly collected in the collection area 150.

As an optional embodiment, the water collection area 150 may be disposed below the intake area (not shown) through which external air flows into the cooling tower 100, based on the direction of gravity (G).

The power generation member 130 may be disposed between the heat exchange area 120 and the water collection area 150 based on the direction of gravity (G). The power generation member 130 may be formed to generate electrical energy by moving with heat-exchanged coolant.

For example, the power generating member 130 may include one or more moving members, and as a specific example, may include a rotating member.

The power generation member 130 is disposed between the heat exchange area 120 and the water collection area 150 based on the direction of gravity (G), and can move by the coolant naturally descending from the heat exchange area 120, For example, a moving member (eg, a rotating member) of the power generating member 130 may move (rotate), and through this movement, the power generating member 130 may generate power.

Meanwhile, the cooling water that has passed through the power generation member 130 may be configured to move to the water collection area 150. For example, based on the direction of gravity (G), the water collection area 150 is disposed lower than the power generation member 130, so that the cooling water that provided the kinetic force to the power generation member 130 flows smoothly into the water collection area 150. can be collected.

As an optional embodiment, the power generation member 130 includes a control unit (BJ), and the control unit (BJ) converts kinetic energy generated through the movement of the power generation member 130 into electrical energy or processes various signals for this purpose. It can be done.

The power generating member 130 may have various shapes, for example, may have a water wheel shape that rotates along one axis due to the movement of coolant.

As an optional embodiment, the power generation member 130 may be arranged to overlap the heat exchange area 120 based on the direction of gravity (G), thereby effectively using energy from the cooling water flowing downward from the heat exchange area 120. This can improve power generation efficiency.

In addition, as an optional embodiment, the power generation member 130 may be arranged to overlap the water collection area 150 based on the direction of gravity (G), through which the cooling water flowing downward from the heat exchange area 120 generates power. After passing through the member 130 and providing a kinetic force to the power generating member 130, the coolant is quickly collected in the water collection area 150, thereby improving the coolant utilization characteristics.

The power generation member 130 may have various sizes, for example, at least a size smaller than the water collection area 150 or the heat exchange area 120, and as a specific example, a small width (based on the direction intersecting the direction of gravity action). It can be formed to have.

The cooling tower of this embodiment can smoothly use low-temperature cooling water by collecting coolant whose temperature has been lowered by performing heat exchange in the heat exchange area supplied through the water supply unit and collecting it in the water collection area. At this time, the coolant cooled in the heat exchange area may have potential energy and kinetic energy, and such energy may cause the power generation member to move and generate power. For example, the power generation member may be formed in the form of a water wheel like a generator to generate power, and the cooling water that has passed through the power generation member may be collected in a water collection area to secure low-temperature cooling water and additionally generate power.

Through this, power can be easily generated along with cooling the cooling water when operating the cooling tower, and this power can be used to drive the cooling tower. As another example, the power can be stored or transmitted for use in other devices.

FIG. 2 is a schematic diagram of a cooling tower according to an alternative embodiment of the cooling tower of FIG. 1.

Referring to FIG. 2 , the cooling tower 100 may include a water supply unit 110, a heat exchange area 120, a water collection area 150, a power generation member 130, and a cooling water guide unit 140.

For convenience of explanation, the description will focus on differences from the above-described embodiment of FIG. 1.

In FIG. 2 , the coolant guide unit 140 has been added compared to FIG. 1 , and the coolant guide unit 140 will now be described.

The coolant guide unit 140 may be disposed between the heat exchange area 120 and the power generation member 130. For example, the coolant guide unit 140 may be disposed between the heat exchange area 120 and the power generation member 130 based on the direction of gravity (G).

The coolant guide unit 140 may be formed to guide the movement direction of the coolant descending from the heat exchange area 120. For example, the coolant guide unit 140 may be formed to guide at least a portion of the coolant descending from the heat exchange area 120 toward the power generation member 130. Through this, power generation efficiency through the power generation member 130 can be improved.

In addition, as an optional embodiment, the coolant guide unit 140 changes the descent path of at least one area when descending from the heat exchange area 120 to the water collection area 150 and then collects the water into the water collection area 150, so that when descending directly from the heat exchange area 120 to the water collection area 150 The noise generated can be reduced.

Figure 3 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 3 , the cooling tower 200 may include a water supply unit 210, a heat exchange area 220, a water collection area 250, a power generation member 230, and a cooling water coil unit 260.

The water supply unit 210 may be arranged to supply cooling water to exchange heat with air introduced from the outside.

Although not shown, the cooling tower 200 of this embodiment may have various shapes, and as an example, it includes a housing (not shown), and at least one area of the water supply unit 210 is disposed inside the housing (not shown). Cooling water can be supplied.

The water supply unit 210 may have various shapes, and as an example, may include one or more pipe shapes having an area through which cooling water supplied from the outside passes, and may have a structure in which a plurality of nozzles connected to these pipe shapes are formed. You can.

The water supply unit 210 may be formed to supply cooling water downward, for example, in the direction of gravity (G).

Although not shown, the cooling tower 200 may include one or more intake areas (not shown) formed to allow external air to flow in, for example, to allow air to flow into the inside of the housing (not shown). As a specific example, one or more intake areas (not shown) may be formed lower than the water supply unit 210 based on the direction of gravity (G).

Although not shown, an exhaust area (not shown) may be formed in one area of the cooling tower 200, for example, one side, or at least one area on the upper side as a specific example. The “upper side” is an area opposite to the direction of gravity (G), and as an optional embodiment, an exhaust area (not shown) may be formed on the upper side of the water supply unit 210.

Heated gas used in coolant heat exchange or other residual gas may be discharged to the outside through this exhaust area (not shown). Additionally, as an optional embodiment, one or more blowing members may be further disposed to correspond to this exhaust area (not shown).

The heat exchange area 220 may be disposed in an area where the cooling water supplied through the water supply unit 210 overlaps.

For example, the heat exchange area 220 may be disposed lower than the water supply unit 210 based on the direction of gravity (G).

Cooling water supplied (for example, sprayed) through the water supply unit 210 may undergo a heat exchange process in the heat exchange area 220, and, as an example, may undergo a heat exchange process with air introduced from the outside.

The heat exchange area 220 may have various shapes, for example, may be formed to include a filling member that fills the inner space of the housing (not shown), and the surface or plurality of filling members of the heat exchange area 220 may be formed. In the space between the filling members, the heat exchange process may proceed as the coolant flows in the direction of gravity (G) and the air moves in the opposite direction.

The water collection area 250 may include an area where the coolant heat-exchanged in the heat exchange area 220 is collected. As an example, the water collection area 250 may be placed lower than the heat exchange area 220 based on the direction of gravity (G).

The coolant whose temperature has been lowered through the heat exchange process in the heat exchange area 220 may be moved to one area, for example, in the direction of gravity action (G), and as a specific example, may be moved naturally to the water collection area 250 by gravity. You can. Through this, the cooling water whose temperature has been lowered can be smoothly collected in the collection area 250.

As an optional embodiment, the water collection area 250 may be disposed below the intake area (not shown) through which external air flows into the cooling tower 200, based on the direction of gravity (G).

The cooling water coil unit 260 may be disposed in at least one area above the water supply unit 210 . For example, the water supply unit 210 and the heat exchange area 220 may be disposed lower than the coolant coil unit 260 based on the direction of gravity (G).

High-temperature coolant flows in through the coolant coil unit 260, and the coolant can move from the coolant coil unit 260 to the water supply unit 210.

The hot coolant flowing through the coolant coil unit 260 may move to the water supply unit 210 after being primarily cooled through external air, for example, external air in contact with or introduced into one side of the coolant coil unit 260. . Additionally, relatively cold outside air may be heated through the coolant coil unit 260 (for example, generating high temperature dry air). Meanwhile, while passing through the heat exchange area 220, the humid air is heated by heated air (e.g., high-temperature dry air) through the cooling water coil unit 260, and the moisture content is reduced, resulting in the cooling tower 200. White smoke can be reduced through

The power generation member 230 may be disposed between the coolant coil unit 260 and the water supply unit 210 based on the direction of gravity (G). The power generation member 230 may be formed to generate electrical energy by moving with coolant moving from the coolant coil unit 260 to the water supply unit 210.

For example, the power generating member 230 may include one or more moving members, and as a specific example, may include a rotating member.

The power generation member 230 is disposed between the coolant coil unit 260 and the water supply unit 210 based on the direction of gravity (G), and can move by the coolant directed toward the water supply unit 210, e.g. For example, the moving member (eg, rotating member) of the power generating member 230 may move (rotate), and the power generating member 230 may generate power by this movement.

As an optional embodiment, an accommodating part (not shown) may be located between the coolant coil unit 260 and the water supply unit 210, and the power generating member 230 may be disposed in the accommodating part (not shown).

As an optional embodiment, the power generation member 230 includes a control unit (BJ), and the control unit (BJ) converts kinetic energy generated through the movement of the power generation member 230 into electrical energy or processes various signals for this purpose. It can be done.

The power generating member 230 may have various shapes, for example, may have a water wheel shape that rotates along one axis due to the movement of coolant.

The cooling tower of this embodiment can smoothly use low-temperature cooling water by collecting coolant whose temperature has been lowered by performing heat exchange in the heat exchange area supplied through the water supply unit and collecting it in the water collection area. In addition, the cooling efficiency of the coolant can be improved by allowing the high-temperature coolant to first pass through the coolant coil part and then moving to the water supply part after being first cooled. In addition, the external air passing through the cooling water coil unit may be high-temperature dry air, and this high-temperature dry air is mixed with high-temperature and humid air passing through the heat exchange area, and as a result, air with reduced humidity is exhausted and the overall temperature of the cooling tower is exhausted. White smoke generation can be reduced.

At this time, the cooling water heading from the cooling water coil unit to the water supply unit may have potential energy and kinetic energy, and this energy causes the power generating member to move and generate power. For example, the power generation member may be formed in the form of a water wheel, such as a generator, to generate power.

Through this, power can be easily generated along with cooling the cooling water when operating the cooling tower, and this power can be used to drive the cooling tower. As another example, the power can be stored or transmitted for use in other devices.

Figure 4 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 4, the cooling tower 300 includes a water supply unit 310, a heat exchange area 320, a water collection area 350, a first power generation member 331, a second power generation member 332, and a cooling water coil unit ( 360).

For convenience of explanation, the description will focus on differences from the above-described embodiment.

The first power generation member 331 may be disposed between the heat exchange area 320 and the water collection area 350 based on the direction of gravity (G), and the power generation member 130 of FIG. 1 or 2 described above. ) or can be modified within a similar range, so a more detailed description will be omitted.

The second power generation member 332 may be disposed between the coolant coil unit 360 and the water supply unit 310 based on the direction of gravity (G), and the power generation member 230 of the embodiment of FIG. 3 described above. ) or can be modified within a similar range, so a more detailed description will be omitted.

Although not shown, the coolant guide part of FIG. 2 may be further included as an optional embodiment.

The cooling tower of this embodiment can smoothly use low-temperature cooling water by collecting coolant whose temperature has been lowered by performing heat exchange in the heat exchange area supplied through the water supply unit and collecting it in the water collection area. In addition, the cooling efficiency of the coolant can be improved by allowing the high-temperature coolant to first pass through the coolant coil part and then moving to the water supply part after being first cooled. In addition, the external air passing through the cooling water coil unit may be high-temperature dry air, and this high-temperature dry air is mixed with high-temperature and humid air passing through the heat exchange area, and as a result, air with reduced humidity is exhausted and the overall temperature of the cooling tower is exhausted. White smoke generation can be reduced.

Meanwhile, the coolant cooled in the heat exchange area may have potential energy and kinetic energy, and this energy causes the first power generation member to move and generate power. Additionally, the coolant flowing from the coolant coil unit to the water supply unit may have potential energy and kinetic energy, and this energy causes the second power generation member to move and generate power. For example, the power generation member may be formed in the form of a water wheel, such as a generator, to generate power.

Through this, power can be easily generated along with cooling the cooling water when operating the cooling tower, and this power can be used to drive the cooling tower. As another example, the power can be stored or transmitted for use in other devices.

Figure 5a is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 5A , the cooling tower 1100 may include a water supply unit 1110, a heat exchange area 1120, a water collection area 1150, and a power generation member 1130.

As shown in FIG. 5A, the cooling tower 1100 may have an external boundary (housing, cover, casing, frame, etc.), and at least one area of the water supply unit 1110, a heat exchange area 1120, and a water collection unit are located in the inner space. Area 1150 and power generating member 1130 may be disposed.

Meanwhile, as an optional embodiment, the cooling tower 1100 may include an exhaust unit 1090 in at least one area on the upper side, and the exhaust unit 1090 has at least one area open and cools through the exhaust unit 1090. Heated gas used for heat exchange or other residual gas may be discharged to the outside.

As an optional embodiment, one or more blowing units 1031 may be disposed to correspond to the exhaust units 1090. For example, the blower 1031 may have a fan shape.

External air may be introduced into the inner space of the cooling tower 1100 through the movement, for example, rotational movement, of the blower 1031, and, for example, the external air may flow smoothly through the first intake unit 1020. It can be allowed to flow in. In addition, through the movement of the blower 1031, the air that has exchanged heat with the coolant can move in the direction of the exhaust unit 1090 and be smoothly exhausted.

The first intake portion 1020 may be formed to allow air to flow into the inside of the cooling tower 1100. For example, the first intake portion 1020 may be formed on one side of the outer boundary of the cooling tower 1100, such as a housing. can be formed in

As an optional embodiment, the first intake portion 1020 may be formed in a plurality of areas, for example, may be formed to correspond to opposite sides.

The water supply unit 1110 may be arranged to supply cooling water to exchange heat with air introduced from the outside.

The water supply unit 1110 is formed to supply cooling water, for example, to supply cooling water to exchange heat with air flowing into the first intake unit 1020.

As an optional embodiment, the water supply unit 1110 may be disposed above the first intake unit 1020, for example, between the first intake unit 1020 and the exhaust unit 1090, and perform heat exchange to be described later. It may be placed above the area 1120.

The heat exchange area 1120 may be disposed in an area where the cooling water supplied through the water supply unit 1110 overlaps.

For example, the heat exchange area 1120 may be disposed lower than the water supply unit 1110 based on the direction of gravity.

Cooling water supplied (for example, sprayed) through the water supply unit 1110 may undergo a heat exchange process in the heat exchange area 1120, and, as an example, may undergo a heat exchange process with air introduced from the outside.

The heat exchange area 1120 may have various forms, for example, may be formed to include a filling member that fills the inner space of the housing (not shown), and the surface or plurality of filling members of the heat exchange area 1120 may be formed. In the space between the filling members, the heat exchange process may proceed as the coolant flows in the direction of gravity (G) and the air moves in the opposite direction.

The water collection area 1150 may include an area where coolant heat-exchanged in the heat exchange area 1120 is collected. As an example, the water collection area 1150 may be placed lower than the heat exchange area 1120 based on the direction of gravity.

Additionally, as an optional embodiment, the water collection area 1150 may be disposed in a lower area than the first intake unit 1020.

The power generation member 1130 may be disposed between the heat exchange area 1120 and the water collection area 1150 based on the direction of gravity. The power generation member 1130 may be formed to generate electrical energy by moving with heat-exchanged coolant.

For example, the power generating member 1130 may include one or more moving members, as a specific example, a rotating member, and may have the form of an aberration.

As an optional embodiment, the coolant guide unit 1140 may be disposed between the heat exchange area 1120 and the power generation member 1130. For example, the coolant guide unit 1140 may be disposed between the heat exchange area 1120 and the power generation member 1130 based on the direction of gravity.

The coolant guide unit 1140 may be formed to guide the movement direction of the coolant descending from the heat exchange area 1120. For example, the coolant guide portion 1140 includes a passage portion WD formed such that at least a portion of the coolant descending from the heat exchange area 1120 is directed toward the power generating member 1130, and corresponds to the passage portion WD. Power generating member 1130 may be disposed. Cooling water may be collected in the water collection area 1150 after passing through the power generation member 1130 through this passage portion WD.

Like the above-described embodiments, the cooling tower of this embodiment can easily use low-temperature cooling water by lowering the temperature of the high-temperature cooling water, and at the same time, utilizes the energy of the cooling water to move the power generation member to facilitate power generation. can do.

As an optional embodiment, an eliminator 1280 may further be included. The eliminator 1280 may be placed above the water supply unit 1110. For example, the eliminator 1280 may be placed between the water supply unit 1110 and the exhaust unit 1090.

After the air introduced through the first intake unit 1202 undergoes a heat exchange process to increase temperature and humidity, the remaining moisture may be reduced, removed, or dispersed by the eliminator 1280.

FIGS. 5B to 5D are diagrams for explaining various modifications of FIG. 5A.

Referring to FIG. 5B, the coolant guide portion 1140 may be created to primarily contact the coolant and change the direction in which it falls into the water collection area 1250. Coolant flows through the coolant guide unit 1140 in one direction, for example, a direction intersecting the direction in which the coolant falls, as a specific example, along the length or width direction (X-axis direction in FIG. 5b) of the coolant guide unit 1140. After moving, it may be moved to the catchment area 1250.

Additionally, the coolant may be delivered after passing through the passage portion WD. Through this, it is possible to reduce or prevent loud noise and noise generated when a large amount of coolant falls into the water collection area 1250. Meanwhile, at this time, power may be generated by the power generation member 1130.

The height H2 of the coolant guide portion 1140 may be determined in various ways, for example, it may be the distance from the heat exchange area 1120. The height H2 of the coolant guide portion 1140 may be smaller than the distance H1 between the heat exchange area 1120 and the water collection area 1250, for example, the bottom of the water collection area 1250. In an alternative embodiment the height H2 may be less than half the distance H1.

As another example, referring to FIGS. 5C and 5D, the coolant guide portion 1140' may include an inclined portion 1141', a support portion 1142', and a connection side portion 1143'.

FIG. 5D is a schematic perspective view illustrating the coolant guide portion 1140' of FIG. 5C in detail. Additionally, as an optional embodiment, this coolant guide unit 1140' may be applied to at least one of the embodiments described later, for example, to a coolant downward direction setting unit.

The arrows in FIGS. 5C and 5D may exemplarily indicate the direction of movement of coolant.

Referring to FIGS. 5C and 5D, the coolant guide portion 1140' has one or more, for example, a plurality of inclined portions 1141', and the inclined portions 1141' have an inclined shape corresponding to the direction in which the coolant falls. You can have it. The inclined portion 1141c' may include an area in contact with coolant falling from the heat exchange area 1120, and the coolant reaches and contacts the plurality of inclined portions 1141' before reaching the water collection area 1150. , Through this, the level of noise generated when the coolant falls and comes into contact with the falling surface can be reduced. Additionally, the coolant can flow along the inclined direction of the inclined portion 1141', thereby reducing noise generation and increasing noise reduction characteristics.

The plurality of inclined portions 1141' may be connected to the support portion 1142', for example, the plurality of support portions 1142' may correspond to each of the plurality of inclined portions 1141', and the plurality of inclined portions 1142' may be connected to the support portion 1142'. It may be connected to (1141') and arranged so that the coolant flows toward the plurality of inclined portions (1141') along the plurality of inclined portions (1141').

Each of the plurality of inclined portions 1141' may have an upper portion, for example, an area facing the inclined portion 1141', open so that coolant can easily collect and flow, and may have a concave shape in the opposite direction. As an optional embodiment, the plurality of inclined portions 1141' may have a curved bottom surface.

The plurality of inclined parts 1141' may be commonly connected to the inner space of the connection side part 1143'. Although not shown, a plurality of inclined portions 1141' may be connected to the inner space of two connecting side portions 1143' facing each other.

The inner space of the connection side portion 1143' may be connected to the passage portion WD, and the coolant flowing through the plurality of inclined portions 1141' may collect and flow in the inner space of the connection side portion 1143', and the passage portion WD may be connected to the inner space of the connection side portion 1143'. You can proceed to the catchment area 1150 through . At this time, power generation can be facilitated through the power generation member 1130 disposed in the passage portion WD.

As an optional embodiment, as shown in FIG. 5D, the plurality of inclined portions 1141' include curved surfaces, for example, convex portions C1 and concave portions C2, to increase the contact surface when coolant falls. The noise reduction effect can be improved through natural falling.

As an optional embodiment, the support portion 1142' may be formed to have a small inclination relative to the longitudinal direction so that coolant flows easily from the support portion 1142' to the connection side portion 1143'.

A plurality of inclined portions 1141' are disposed in the area where the coolant falls at the lower part of the heat exchange area 1120 and come into contact with the coolant, thereby reducing or preventing loud noise from being generated on the falling surface when the coolant falls, Each of the plurality of inclined portions 1141' is connected to each other in one direction, for example, to the connection side 1143' through the support portion 1142', and from the connection side 1143' to the passage portion WD. The power generation efficiency of the power generation member 1130 can be improved by allowing the coolant to flow effectively in this direction. In addition, when the coolant falls, it reaches the water collection area 1150 after passing through the power generating member 1130, thereby reducing the level of noise generated in the water collection area 1150. FIG. 6 shows another embodiment of the present invention. This is a drawing schematically showing a cooling tower.

Referring to FIG. 6 , the cooling tower 1200 may include a water supply unit 1210, a heat exchange area 1220, a water collection area 1250, and a power generation member 1230.

As shown in FIG. 6, the cooling tower 1200 may include a housing 1201, which is an external boundary.

The housing 1201 may be formed to have a space inside. For example, the housing 1201 may have a shape similar to a box.

As an optional embodiment, the exhaust unit 1290 may be formed in one area of the housing 1201, for example, on one side, as a specific example, at least one area on the upper side.

As an optional embodiment, one or more blowing units 1293 may be disposed to correspond to the exhaust units 1290. For example, the blowing unit 1293 may include a blowing member 1291 and a driving member 1292. As a specific example, the blowing member 1291 may have a fan shape, and the driving member 1292 may include a blowing member 1292. It may have the form of a motor member that provides driving force to rotate (1291).

External air can be smoothly introduced through the first intake unit 1202 through the movement, for example, rotation, of the blowing member 1291.

As an optional embodiment, when the second intake unit 1225 is formed to introduce low-temperature, low-humidity external air to be mixed with the high-temperature, high-humidity air heat-exchanged with the cooling water, the movement of the blowing member 1291 causes the second intake unit 1225 to be formed. It is possible to allow outside air to flow in smoothly. Additionally, through the movement of the blowing member 1291, the air inside the housing 1201, for example, the air that has exchanged heat with the coolant, can move in the direction of the exhaust unit 1290 and be smoothly exhausted.

The first intake portion 1202 may be formed to allow air to flow into the inside of the cooling tower 1200. For example, the first intake portion 1202 may be formed in one area of the outer boundary of the housing 1201. You can.

As an optional embodiment, the first intake portion 1202 may be formed in a plurality of areas, for example, may be formed to correspond to opposite sides.

The water supply unit 1210 may be arranged to supply cooling water to exchange heat with air introduced from the outside.

The water supply unit 1210 is formed to supply cooling water, for example, to supply cooling water to exchange heat with the air flowing into the first intake unit 1202.

As an optional embodiment, the water supply unit 1210 may be disposed above the first intake unit 1202, for example, between the first intake unit 1202 and the exhaust unit 1090, and perform heat exchange to be described later. It may be placed above the area 1220.

The water supply unit 1210 may have various forms and, as an example, may include a water supply body 1211 and a water supply nozzle 1212. The water supply body 1211 is a path along which cooling water moves, for example, may be an area through which cooling water supplied from the outside passes, and as a specific example, may have the shape of one or more pipes. The water supply nozzles 1212 may be arranged in plural numbers, and when the water supply body 1211 has a plurality of pipe shapes, a plurality of water supply nozzles 1212 may be arranged in each pipe shape. The water nozzle 1212 may be formed to spray coolant toward the lower side, for example, air introduced into the inner space of the housing 1201 through the first intake portion 1202.

The heat exchange area 1220 may be disposed in an area where the cooling water supplied through the water supply unit 1210 overlaps.

For example, the heat exchange area 1220 may be disposed lower than the water supply unit 1210 based on the direction of gravity.

Cooling water supplied (for example, sprayed) through the water supply unit 1210 may undergo a heat exchange process in the heat exchange area 1220, and, as an example, may undergo a heat exchange process with air introduced from the outside.

The heat exchange area 1220 may have various shapes, for example, may be formed to include a filling member that fills the inner space of the housing (not shown), and the surface or plurality of filling members of the heat exchange area 1220 may be formed. In the space between the filling members, the heat exchange process may proceed as the coolant flows in the direction of gravity (G) and the air moves in the opposite direction.

The shape and type of the filling member of the heat exchange area 1220 may be determined in various ways and may be determined depending on the type of cooling tower and cooling water. The filling member may be made of various materials, may be formed using inorganic or organic materials, and may contain, for example, a resin-based material.

The water collection area 1250 may include an area where coolant heat-exchanged in the heat exchange area 1220 is collected. As an example, the water collection area 1250 may be placed lower than the heat exchange area 1220 based on the direction of gravity.

Additionally, as an optional embodiment, the water collection area 1250 may be disposed in a lower area than the first intake unit 1020.

The power generation member 1230 may be disposed between the heat exchange area 1220 and the water collection area 1250 based on the direction of gravity. The power generation member 1230 may be formed to generate electrical energy by moving with heat-exchanged coolant.

For example, the power generating member 1230 may include one or more moving members, as a specific example, a rotating member, and may have the form of an aberration.

As an optional embodiment, the coolant guide unit 1240 may be disposed between the heat exchange area 1220 and the power generation member 1230. For example, the coolant guide unit 1240 may be disposed between the heat exchange area 1220 and the power generation member 1230 based on the direction of gravity.

The coolant guide unit 1240 may be formed to guide the movement direction of the coolant descending from the heat exchange area 1220. For example, the coolant guide portion 1240 includes a passage portion WD formed such that at least a portion of the coolant descending from the heat exchange area 1220 is directed toward the power generation member 1230, and corresponds to the passage portion WD. Power generating member 1230 may be disposed. Cooling water may be collected in the water collection area 1250 after passing through the power generating member 1230 through this passage portion WD.

As an optional embodiment, a heating unit 1270 may be further disposed. The heating unit 1270 may be disposed inside the housing 1201, and may be disposed above the water supply unit 1210, for example, above the second intake unit 1225. As a specific example, the second intake unit 1225 may be disposed above the water supply unit 1210. It may be disposed between the intake unit 1225 and the exhaust unit 1290.

The temperature of the air introduced through the first intake unit 1202 increases through a heat exchange process, and can be heated by the heating unit 1270 and, for example, mixed with the air introduced through the second intake unit 1225. After being heated, it can be heated by the heating unit 1270.

Various types and shapes of the heating unit 1270 can be applied. As an example, the housing 1201 may have various types of heat generated inside, and may include a heating coil as a specific example.

As an optional embodiment, the heating unit 1270 may have a shape extending in one direction on the inside of the housing 101, for example, having a shape extending in a direction from one side toward the inside of the housing 1201. You can have

In addition, as another optional embodiment, the heating unit 1270 extends in one direction inside the housing 1201, for example, in the height direction of the housing 1201 (for example, the Z-axis direction in FIG. 6). Depending on the length, it may have an extended form.

As an optional embodiment, an eliminator 1280 may further be included. The eliminator 1280 may be placed inside the housing 1201 and above the water supply unit 1210. For example, the eliminator 1280 may be disposed above the second intake unit 1225, and as a specific example, between the second intake unit 1225 and the exhaust unit 1290 on the inside of the housing 1201. can be placed in

After the air introduced through the first intake unit 1202 undergoes a heat exchange process to increase temperature and humidity, the remaining moisture may be reduced, removed, or dispersed by the eliminator 1280.

In the cooling tower of this embodiment, cooling water is supplied to the inside of the housing through the water supply part, air can be introduced into the inside of the housing through the first intake part, and, for example, external air is easily sucked in through the blower part. It can flow into the inside of the. In the heat exchange area, the coolant and the air introduced through the first intake part may come into contact and a heat exchange process may proceed. The coolant whose temperature has been lowered through this process is collected again, for example, in a water collection area, and can be moved to a place where the coolant needs to be used.

At this time, power generation can be easily performed by using the energy of the cooling water moving from the heat exchange area to the water collection area to move the power generation member.

In addition, as an optional embodiment, air may be introduced into the inside of the housing from the outside through a second intake part provided separately from the first intake part, for example, disposed on the upper side, and this introduced outside air may pass through the heat exchange area. It can be mixed with high temperature and high humidity air. Through this mixed air, the white smoke phenomenon in the exhaust air discharged toward the exhaust part can be reduced.

Figure 7 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 7 , the cooling tower 2000 may include a water supply unit 2210, a heat exchange area 2220, a water collection area 2250, and a power generation member 2230.

As shown in FIG. 7, the cooling tower 2000 may include a housing 2201, which is an external boundary. As an optional embodiment, the exhaust unit 2290 may be formed in one area of the housing 2201, for example, on one side, as a specific example, at least one area on the upper side. As an optional embodiment, one or more blowing units 2293 may be disposed to correspond to the exhaust units 2290. For example, the blowing unit 2293 may include a blowing member 2291 and a driving member 2292.

For convenience of explanation, the description will focus on differences from the embodiment of FIG. 6 described above.

The first intake unit 2202, the water supply unit 2210, the heat exchange area 2220, and the water collection area 2250 are the same as those described in the above-described embodiment, and a more detailed description will be omitted.

As an optional embodiment, a heating unit 2270 and an eliminator 2280 may be further included, and since they are the same as those described in the above-described embodiment, a more detailed description will be omitted.

The power generation member 2230 may be disposed between the heat exchange area 2220 and the water collection area 2250 based on the direction of gravity. The power generation member 2230 may be formed to generate electrical energy by moving with heat-exchanged coolant.

For example, the power generating member 2230 may include one or more moving members, as a specific example, a rotating member, and may have the form of an aberration.

As an optional embodiment, the coolant guide unit 2240 may be disposed between the heat exchange area 2220 and the power generation member 2230. For example, the coolant guide unit 2240 may be disposed between the heat exchange area 2220 and the power generation member 2230 based on the direction of gravity.

The coolant guide unit 2240 may be formed to guide the movement direction of the coolant descending from the heat exchange area 2220. The coolant guide portion 2240 may include a base portion 2241 connected to the passage portion WD. Cooling water can be concentrated in the passage part WD through the base part 2241.

Additionally, the coolant guide unit 2240 may include a coolant downward direction setting unit 2242. As an example, the coolant downward direction setting unit 2242 may include an inclined plate area so that coolant flows in one direction, and as a specific example, may include a plurality of inclined plates spaced apart from each other.

This coolant downward direction setting unit 2242 may be connected to the connection member 2243, and at least the connection member 2243 may be connected to the connection member 2243 so that the plurality of inclined plates are commonly connected to the connection member 2243. 2242).

As an optional embodiment, the connecting member 2243 may be omitted, in which case the coolant downward direction setting portion 2242 may be connected to one area of the heat exchange area 2220, for example, the lower end of the heat exchange area 220. can be connected to

The cooling water descending direction from the heat exchange area 2220 to the water collection area 2250 is allowed to flow as desired through the cooling water descending direction setting unit 2242, thereby improving the efficiency of generating power through the cooling water smoothly to the power generation member 2230. can do.

In addition, the generation of uneven noise that occurs when the material falls irregularly directly from the heat exchange area 2220 to the water collection area 2250 can be reduced. As a specific example, when the coolant downward direction setting unit 2242 includes a plurality of inclined plates, the direction can be changed by reducing noise while primarily contacting the coolant through the plurality of plates, and secondarily, the base part 2241 and the like. By allowing the water to flow to the water collection area 2250 through the connected passageway WD, noise, especially uneven noise generation, can be reduced.

Figure 8 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 8, the cooling tower 3000 may include a water supply unit 3210, a heat exchange area 3220, a water collection area 3250, and a power generation member 3230.

As shown in FIG. 8, the cooling tower 3000 may include a housing 3201, which is an external boundary. As an optional embodiment, an exhaust portion 3290 may be formed in one area of the housing 3201, for example, on one side, as a specific example, at least one area on the upper side. As an optional embodiment, one or more blowing units 3293 may be disposed to correspond to the exhaust units 3290. For example, the blowing unit 3293 may include a blowing member 3291 and a driving member 3292.

For convenience of explanation, the description will focus on differences from the above-described embodiment of FIG. 7.

The first intake unit 3202, the water supply unit 3210, the heat exchange area 3220, and the water collection area 3250 are the same as those described in the above-described embodiment, and further detailed descriptions will be omitted.

As an optional embodiment, a heating unit 3270 and an eliminator 3280 may be further included, and since they are the same as those described in the above-described embodiment, a more detailed description will be omitted.

The power generation member 3230 may be disposed between the heat exchange area 3220 and the water collection area 3250 based on the direction of gravity. The power generation member 3230 may be formed to generate electrical energy by moving with heat-exchanged coolant.

For example, the power generating member 3230 may include one or more moving members, as a specific example, a rotating member, and may have the form of an aberration.

As an optional embodiment, the coolant guide unit 3240 may be disposed between the heat exchange area 3220 and the power generation member 3230. For example, the coolant guide unit 3240 may be disposed between the heat exchange area 3220 and the power generation member 3230 based on the direction of gravity.

The coolant guide unit 3240 may be formed to guide the movement direction of the coolant descending from the heat exchange area 3220. The coolant guide portion 3240 may include a base portion 3241 connected to the passage portion WD. Coolant can be concentrated in the passage section (WD) through the base portion 3241.

Additionally, the coolant guide unit 3240 may include coolant downward direction setting units 3242A and 3242B. As an example, the coolant downward direction setting units 3242A and 3242B may include an inclined plate area so that the coolant flows in one direction, and as a specific example, the first direction setting unit 3242A may include a plurality of inclined plates spaced apart from each other. may include, and the second direction setting unit 3242B may include a plurality of inclined plates spaced apart from each other. At this time, the direction in which the inclined plate of the first direction setting unit 3242A is inclined may be different from the inclined direction of the inclined plate of the second direction setting unit 3242B, and for example, may be directions that intersect each other. Additionally, as a specific example, the direction in which the inclined plates of the first direction setting unit 3242A are inclined may have a shape in which the inclined plates of the second direction setting unit 3242B approach each other in a direction.

Through this, the coolant can be effectively concentrated in the passageway (WD).

In the drawing, the passage portion WD is adjacent to the center in the width direction of the water collection area 3250, but may be disposed in an area adjacent to the side away from the center.

Figure 9 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 9, the cooling tower 4000 may include a water supply unit 4210, a heat exchange area 4220, a water collection area 4250, a power generation member 4230, and a cooling water coil unit 4260.

As shown in FIG. 9, the cooling tower 4000 may include a housing 4201, which is an external boundary. As an optional embodiment, an exhaust portion 4290 may be formed in one area of the housing 4201, for example, on one side, as a specific example, at least one area on the upper side. As an optional embodiment, one or more blowing units 4291 may be disposed to correspond to the exhaust units 4290.

For convenience of explanation, the description will focus on differences from the above-described embodiment.

The water supply unit 4210 may be arranged to supply cooling water to exchange heat with air introduced from the outside, and may include a water supply body 4211 and a water supply nozzle 4212 in the same or similar manner as described in the above-described embodiments. there is

The heat exchange area 4220 may be disposed in an area where the cooling water supplied through the water supply unit 4210 overlaps.

For example, the heat exchange area 4220 may be disposed lower than the water supply unit 4210 based on the direction of gravity, and since variations are applied in the same or similar range as described in the above-described embodiments, detailed descriptions will be omitted.

The water collection area 4250 may include an area where coolant heat-exchanged in the heat exchange area 4220 is collected. As an example, the water collection area 4250 may be placed lower than the heat exchange area 4220 based on the direction of gravity.

Additionally, as an optional embodiment, the water collection area 4250 may be disposed in a lower area than the first intake unit 4202.

The cooling water coil unit 4260 may be disposed in at least one area above the water supply unit 4210. For example, the water supply unit 4210 and the heat exchange area 4220 may be disposed lower than the cooling water coil unit 4260 based on the direction of gravity.

The cooling water coil unit 4260 may be placed on one side or close to one side of the cooling tower 4000 for heat exchange through outside air. For example, at least one area of the coolant coil unit 4260 may be disposed outside the housing 4201 so as to be adjacent to the side of the housing 4201. Additionally, as another example, it may be placed in the inner space of the housing 4201.

Additionally, it may include an external air inlet 4269 such as a damper formed to allow external air to flow in toward the coolant coil unit 4260.

Coolant with a high temperature flows in through the coolant coil unit 4260, and the coolant can move from the coolant coil unit 4260 to the water supply unit 4210.

The hot coolant flowing through the coolant coil unit 4260 exchanges heat with external air introduced through the outside air inlet 4269 and is primarily cooled before moving to the water supply unit 4210.

Additionally, cold air introduced through the outside air inlet 4269 may be heated by heat exchange with the coolant coil unit 4260 (for example, generating high-temperature dry air). Meanwhile, while passing through the heat exchange area 4220, the humid air is heated by heated air (e.g., high-temperature dry air) through the cooling water coil unit 4260, and the moisture content is reduced, resulting in the cooling tower 4000. White smoke can be reduced through

The power generation member 4230 may be disposed between the coolant coil unit 4260 and the water supply unit 4210 based on the direction of gravity. The power generation member 4230 may be formed to generate electrical energy by moving with coolant moving from the coolant coil unit 4260 to the water supply unit 4210.

At this time, it may be spaced apart from the water supply nozzle 4212 and placed outside the water supply nozzle 4212 so as not to affect the water supply nozzle 4212 of the water supply unit 4210.

As an optional embodiment, a receiving portion 4265 may be located between the coolant coil portion 4260 and the water supply portion 4210, and after cooling water is accommodated in the receiving portion 4255, it may be supplied to the water supply portion 4210. . At this time, the power generating member 4230 may be disposed in the receiving portion 4265.

Through this, the power generation member 4230 can smoothly generate power while supplying coolant to the water supply unit 4210 and spraying coolant into the heat exchange area 4220 through the water supply unit 4210.

As an optional embodiment, one or more power generation members 4230 may be arranged, for example, two or more as shown in the drawing.

The power generation member 4230 may be arranged to reduce or eliminate the obstruction area to the inner space of the housing 4201, for example, the power generation member 4230 may be disposed in the housing 4201 as shown in the drawing. It can be placed outside of . Additionally, as another example, it may be placed inside the housing 4201.

As a specific example, the receiving portion 4265 may be arranged close to, for example, adjacent to the side of the housing 4201, or may be arranged adjacent to the outside or inside of the side of the housing 4201.

The cooling tower of this embodiment can smoothly use low-temperature cooling water by collecting coolant whose temperature has been lowered by performing heat exchange in the heat exchange area supplied through the water supply unit and collecting it in the water collection area. In addition, the cooling efficiency of the coolant can be improved by allowing the high-temperature coolant to first pass through the coolant coil part and then moving to the water supply part after being first cooled. In addition, the external air passing through the cooling water coil unit may be high-temperature dry air, and this high-temperature dry air is mixed with high-temperature and humid air passing through the heat exchange area, and as a result, air with reduced humidity is exhausted and the overall temperature of the cooling tower is exhausted. White smoke generation can be reduced.

At this time, the cooling water heading from the cooling water coil unit to the water supply unit may have potential energy and kinetic energy, and this energy causes the power generating member to move and generate power. For example, the power generation member may be formed in the form of a water wheel, such as a generator, to generate power.

Through this, power can be easily generated along with cooling the cooling water when operating the cooling tower, and this power can be used to drive the cooling tower. As another example, the power can be stored or transmitted for use in other devices.

Figure 10 is a diagram schematically showing a cooling tower according to another embodiment of the present invention.

Referring to FIG. 10, the cooling tower 5000 includes a water supply unit 5210, a heat exchange area 5220, a water collection area 5250, a first power generation member 5231, a second power generation member 5232, and a cooling water coil unit ( 5260).

As shown in FIG. 10, the cooling tower 5000 may include a housing 5201, which is an external boundary. As an optional embodiment, an exhaust portion 5290 may be formed in one area of the housing 5201, for example, on one side, as a specific example, at least one area on the upper side. As an optional embodiment, one or more blowing units 5291 may be disposed to correspond to the exhaust units 5290.

For convenience of explanation, the description will focus on differences from the embodiment of FIG. 9 described above.

The first power generation member 5231 may be disposed between the heat exchange area 5220 and the water collection area 5250 based on the direction of gravity. Since it may be the same as the above-described embodiment (for example, the power generation member 2230 of FIG. 7, etc.) or may be modified within a similar range, a more detailed description will be omitted.

In addition, as an optional embodiment, the coolant guide part 2240 of FIG. 7 may be disposed, and in addition, the coolant guide part 1240 of FIG. 6 or the coolant guide part 3240 of FIG. 8 may be selectively applied. A detailed explanation for this will be omitted.

The second power generation member 5232 may be disposed between the coolant coil unit 5260 and the water supply unit 5210 based on the direction of gravity, and is the same as the power generation member 4230 in the embodiment of FIG. 9 described above. Or it can be modified within a similar range, so a more detailed description is omitted.

The cooling tower of this embodiment can smoothly use low-temperature cooling water by collecting coolant whose temperature has been lowered by performing heat exchange in the heat exchange area supplied through the water supply unit and collecting it in the water collection area. In addition, the cooling efficiency of the coolant can be improved by allowing the high-temperature coolant to first pass through the coolant coil part and then moving to the water supply part after being first cooled. In addition, the external air passing through the cooling water coil unit may be high-temperature dry air, and this high-temperature dry air is mixed with high-temperature and humid air passing through the heat exchange area, and as a result, air with reduced humidity is exhausted and the overall temperature of the cooling tower is exhausted. White smoke generation can be reduced.

At this time, the cooling water heading from the cooling water coil unit to the water supply unit may have potential energy and kinetic energy, and this energy causes the power generating member to move and generate power. For example, the power generation member may be formed in the form of a water wheel, such as a generator, to generate power.

Through this, power can be easily generated along with cooling the cooling water when operating the cooling tower, and this power can be used to drive the cooling tower. As another example, the power can be stored or transmitted for use in other devices.

As such, the present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

Specific implementations described in the embodiments are examples and do not limit the scope of the embodiments in any way. Additionally, if there is no specific mention such as “essential,” “important,” etc., it may not be a necessary component for the application of the present invention.

In the specification of the embodiment (particularly in the claims), the use of the term “above” and similar referential terms may refer to both the singular and the plural. In addition, when a range is described in an example, the invention includes the application of individual values within the range (unless there is a statement to the contrary), and is the same as describing each individual value constituting the range in the detailed description. . Lastly, unless the order of the steps constituting the method according to the embodiment is clearly stated or there is no description to the contrary, the steps may be performed in an appropriate order. The embodiments are not necessarily limited by the order of description of the steps above. The use of any examples or illustrative terms (e.g., etc.) in the embodiments is merely for describing the embodiments in detail, and unless limited by the claims, the scope of the embodiments is not limited by the examples or illustrative terms. That is not the case. Additionally, those skilled in the art will recognize that various modifications, combinations, and changes may be made according to design conditions and factors within the scope of the appended claims or their equivalents.

100, 100', 200, 1100, 1200, 2000, 3000, 4000, 5000: Cooling tower
110, 210, 310, 1110, 1210, 2210, 3210, 4210, 5210: Water supply unit
120, 220, 320, 1120, 1220, 2220, 3220, 4220, 5220: Heat exchange area
150, 250, 350, 1150, 1250, 2250, 3250, 4250, 5250: Catchment area
130, 230, 331, 332, 1130, 1230, 2230, 3230, 4230, 5231, 5232: No power generation

Claims (5)

a water supply unit arranged to supply cooling water to be heat-exchanged with air introduced from the outside;
a heat exchange area disposed in an area overlapping with the cooling water supplied through the water supply unit in at least one direction;
a water collection area where coolant heat-exchanged in the heat exchange area is collected; and
A cooling tower comprising a power generating member disposed between the heat exchange area and the water collection area based on the direction of gravity action and generating electrical energy by moving by the heat exchanged cooling water. a water supply unit arranged to supply cooling water to be heat-exchanged with air introduced from the outside;
a heat exchange area disposed in an area overlapping with cooling water supplied through the water supply unit;
a water collection area where coolant heat-exchanged in the heat exchange area is collected;
A coolant coil unit formed to exchange heat with the outside air and allow coolant to move to the water supply unit, and
A cooling tower including a power generating member disposed between the cooling water coil unit and the water supply unit based on the direction of gravity action and moving by the cooling water to generate electrical energy. According to claim 1 or 2,
The power generating member is a cooling tower including a moving member configured to rotate by the cooling water. According to claim 1 or 2,
The power generating member is a cooling tower including a control unit that converts the kinetic force generated by the cooling water into electrical energy or performs signal processing therefor. According to claim 1,
A cooling tower wherein the power generating member is disposed to overlap the heat exchange area or the water collection area.

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