KR101379006B1 - Water Division Cap and Recyling Evaporation Type Cooler Using The Same - Google Patents

Abstract

In order to ensure that the evaporated water is evenly supplied to the wet channel when installed inclinedly, it is possible to easily install several pieces in a prefabricated manner. A plurality of roof claddings which are formed by crossing and protruding from each other, and are formed at regular intervals along both sides of the roof so as to guide the evaporated water from the upper surface of the roof to the lower side of the roof and to support the roof at a predetermined height. It provides an evaporated water distribution cover comprising a plurality of droplet induction pillars.

Description

Water Division Cap and Recyling Evaporation Type Cooler Using The Same}

The present invention relates to an evaporated water distribution cover and a regenerative evaporative cooler using the same, and more particularly, to prevent evaporated water supplied by an evaporated water supply device from flowing into a dry channel and evenly distributed into a wet channel and installed to be inclined. The present invention also relates to an evaporated water distribution cover configured to effectively distribute evaporated water to a wet channel and a regenerative evaporative cooler using the same.

In general, as a device for maintaining indoor air in a comfortable state, a refrigerant vapor compression type cooling device is widely used.

The refrigerant vapor compression type cooling device mainly maintains air temperature by absorbing heat from the surroundings when the liquid evaporates using freon gas, and condenser and refrigerant condensing the evaporator and the refrigerant to evaporate the refrigerant. Is provided with a compressor for compressing the steam at high temperature and high pressure, and an expansion device for reducing the refrigerant pressure.

However, since the cooling device consumes a large amount of energy during operation and causes air pollution due to the use of a refrigerant, in recent years, the cooling device uses an evaporative cooling method to lower the temperature by using latent heat of liquid evaporation. Research and development of the applied regenerative evaporative cooler is being actively conducted.

Republic of Korea Patent Registration No. 0409265 and Patent Registration No. 0713133, etc. describes a technique for applying a regenerative evaporative cooling method.

The Patent Registration No. 0725133 Regenerative Evaporative Cooling Ventilator includes a Regenerative Evaporative Cooler; An air distributor connected to the regenerative evaporative cooler so as to communicate with the regenerative evaporative cooler; A duct communicatively connected to the air distributor, the duct providing a flow passage of the inflow or outflow of air; It is equipped with a bleeding channel formed on the indoor side of the duct so as to open and close, and comprises a bleeding damper for extracting a portion of the air flowing out of the regenerative evaporative cooler to the exhaust evaporative cooler side to exhaust the outdoor air, summer ventilation Not only can the load be greatly reduced, but the cooling load can be reduced rather than without ventilation.

On the other hand, Patent No. 1054445 regenerative evaporative air conditioner is disposed on the upper part of the wet channel, the evaporation water supply unit for supplying the evaporated water to wet the wet channel portion and the gun channel is installed in the upper part of the dry channel portion to separate the wet channel portion Channel guide ducts are described.

The dry channel guide duct can effectively block the inflow of the evaporated water sprayed on the evaporated water supply, and is formed in a substantially "∧" shape.

However, the conventional regenerative evaporative air conditioner configured as described above has a problem that it is difficult to efficiently supply the evaporated water supplied from the evaporated water supply unit evenly to the wet channel because the surface of the dry channel guide duct is made of a flat surface.

In addition, the conventional regenerative evaporative air conditioner has a problem that it is difficult to smoothly discharge air from the gun channel when the gun channel guide duct covers the upper part of the gun channel except for both ends.

In addition, the conventional regenerative evaporative air conditioner has problems such as deterioration of workability and leakage of the connection part when it is necessary to connect several dry channel guide ducts in accordance with the length of the dry channel or the wet channel.

Furthermore, in the conventional regenerative evaporative air conditioner, when the installation heights of both ends of the wet channel are inclined to be inclined differently from each other, the guide ducts are inclined together, so that the evaporated water is lowered to the lower part of the guide duct. Since the evaporated water is concentrated while flowing down, there is a problem that it is difficult to distribute the evaporated water evenly throughout the wet channel.

An object of the present invention is to solve the above problems, block the evaporated water supplied by the evaporative water supply device such as sprinkler flows into the dry channel and evenly distributed throughout the wet channel evenly distributed throughout the wet channel. It is to provide an evaporative water distribution cover which can be used and a regenerative evaporative cooler using the same.

Another object of the present invention is to provide an evaporated water distribution cover and a regenerative evaporative cooler using the same, evenly distributed evenly in the wet channel without being concentrated in one side even when installed in an inclined state.

Evaporation water distribution cover proposed by the present invention is a plurality of roofs are formed by tunnels and roofs formed to protrude across the center and both corners of the roof at regular intervals along the longitudinal direction on the upper surface of the roof. It comprises a water barrier and a plurality of droplet induction pillars are formed at regular intervals along the longitudinal direction on both sides of the roof to guide the evaporated water of the upper surface of the roof to the lower side of the roof and to support the roof at a certain height.

The roof is formed so as to form a cross-section "reverse" as two inclined surfaces are connected.

The roof clasps are arranged in a staggered pattern on both sides with respect to the center of the roof.

The droplet induction column has a substantially bar plate shape and is disposed to correspond to the roof barrier.

The droplet induction pillar may be formed to protrude along one edge and may further be provided with a plurality of pillar barriers connected to the roof barrier.

The roof may be further provided with a plurality of eaves which are formed to be bent outward from both corners and positioned between the upper ends of the droplet induction pillars.

In addition, the regenerative evaporative cooler proposed by the present invention is provided with a heat exchanger which is formed so that a plurality of dry channels and wet channels are alternately and repeatedly arranged alternately by partition walls, and an evaporated water supplying evaporated water from above the heat exchanger. It is formed and formed so as to cover one end surface of the dry channel of the heat exchanger at regular intervals to guide the evaporated water supplied by the evaporated water supply device to the wet channel and to wet the wet channel evenly. It comprises a plurality of the evaporated water distribution cover installed.

The evaporated water distribution cover is installed such that each distance between both edges of the roof and the top end of the key channel of the heat exchanger is maintained at 80% or more of the distance between the partition walls located at both sides of the gun channel.

And a pair of evaporated water distribution cover which is respectively installed above the dry channel located adjacent to each other of the heat exchanger is installed so that the distance between the roof is maintained at 50% or more of the distance between the partition walls on both sides of the wet channel.

According to the present invention, the evaporated water dispensing cover and the regenerative evaporative cooler using the same, the evaporated water is naturally introduced into the wet channel while preventing the evaporated water from flowing into the dry channel, so that the wet channel is uniformly wetted, reducing the amount of evaporated water used and cooling performance. It is possible to improve.

In addition, according to the present invention, the evaporated water distribution cover and the regenerative evaporative cooler using the same ensure a certain distance between the evaporated water distribution cover and between the dry channel and the evaporated water distribution cover, thereby smoothly discharging air passing through the dry channel. It is possible.

In addition, according to the evaporated water distribution cover according to the present invention, even when installed in an inclined state, the evaporated water does not flow down to the low side but is blocked by a roof barrier in the middle and evenly guides the wet channel through the droplet induction pillar. It is possible to wet the wet channel.

Furthermore, according to the present invention, the evaporated water distribution cover can be manufactured in a predetermined length and can be installed while assembling several pieces in a prefabricated manner, thereby facilitating manufacture, improving assemblability and constructability, and preventing leakage of a connection part.

1 is a perspective view showing an embodiment of the evaporated water distribution cover according to the present invention.
Figure 2 is a perspective view of the use state showing an embodiment of the evaporated water distribution cover according to the present invention.
Figure 3 is a front view showing a state of use of one embodiment of the evaporated water distribution cover according to the present invention.
Figure 4 is a plan view showing an embodiment of the evaporated water distribution cover according to the present invention.
Figure 5 is a side view showing an embodiment of the evaporated water distribution cover according to the present invention.
6 is a front view showing an embodiment of the evaporated water distribution cover according to the present invention.
7 is a sectional view taken along the line AA in Fig.
8 is a cross-sectional view taken along line BB of FIG. 5.
9 is a cross-sectional view taken along line CC of FIG. 6.
Figure 10 is an exploded perspective view showing a state connecting two in one embodiment of the evaporated water distribution cover according to the present invention.
11 is a partial cross-sectional side view showing a state in which two are connected in one embodiment of the evaporated water distribution cover according to the present invention.
12 is a side view illustrating a state in which the evaporated water distribution cover according to the present invention is installed and used in an inclined state.
13 is a partially enlarged side view showing a state in which the evaporated water distribution cover according to the present invention is installed and used in an inclined state.
14 is a plan view for explaining the interval of installation of the evaporated water distribution cover in one embodiment of the regenerative evaporative cooler according to the present invention.
15 is a plan view showing a heat exchanger in one embodiment of the regenerative evaporative cooler according to the present invention.

Next, a preferred embodiment of the evaporated water distribution cover and the regenerative evaporative cooler using the same according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description, the same reference numerals are used for the same technical elements, and detailed descriptions for avoiding redundant description are omitted.

The embodiments described below are intended to illustrate the preferred embodiments of the present invention in an effective manner and should not be construed to limit the scope of the present invention.

An embodiment of the evaporated water distribution cover 100 according to the present invention, as shown in Figures 1 to 6, the roof 110, and a plurality of roof barriers 120 formed on the upper surface of the roof 110 and It includes a plurality of droplet induction pillars 140 formed on both sides of the roof 110.

Dotted arrows in the figure indicate the flow direction of the evaporated water.

The roof 110 is installed to cover the upper end surface of the gun channel 20 formed in the heat exchanger 10 of the regenerative evaporative cooler at regular intervals.

The roof 110 is installed in the form of a tunnel that forms a substantially "∧ (reverse v-za)" cross-section as the two inclined surfaces 111 are connected.

The upper surface of the roof 110 may be further formed by forming a partition protrusion 112 which protrudes so that the space above the two inclined surfaces 111 is separated and partitioned.

The roof barrier 120 is installed on the upper surface (inclined surface 111) of the roof 110 so as to protrude from the center and both edges of the roof 110 at regular intervals along the length direction.

As shown in FIG. 8, the roof barrier 120 is formed in a substantially plate shape and is formed to protrude approximately 1 to 10 mm in a vertical direction from an upper surface of the roof 110.

When the roof barrier 120 is installed, it is possible to partition the space above the roof 110 into various spaces along the longitudinal direction, and accordingly, the evaporated water is evenly distributed on the upper surface of the roof 110 in a horizontal state or an inclined state. It is possible.

The roof barrier 120 may be arranged in a staggered pattern on the two inclined surfaces 111 of the roof 110.

When the roof barrier 120 is alternately arranged as described above, when the evaporated water is supplied from the evaporated water supply device 60 installed on the upper side of the heat exchanger 10 to the upper surface of the roof 110, it is diverted as many as possible within a predetermined installation section. It is possible to induce the evaporated water evenly throughout the wet channel 30 of the heat exchanger 10 while dispersing the evaporated water.

The droplet induction column 140 supports the roof 110 at a predetermined height so that the roof 110 is maintained at a predetermined distance from an upper end surface of the top surface of the dry channel 20 of the heat exchanger 10 and the evaporated water supply device 60. Induced by the evaporated water supplied to the upper surface of the roof 110 toward the lower side of the roof 110 is formed to flow through the inner surface of the wet channel 30 of the heat exchanger (10).

The droplet induction pillar 140 is disposed to correspond to the roof barrier 120 to be in parallel with the roof barrier 120.

The droplet induction pillar 140 is formed in a substantially bar plate shape and extends to a lower side where the wet channel 30 of the heat exchanger 10 is located at both edges of the roof 110.

The droplet induction column 140 is installed at regular intervals along the lengthwise direction at both edges of the roof 110 to allow gas such as air to flow into or out of the dry channel 20 of the heat exchanger 10. do.

A plurality of eaves 130 may be further provided between the upper ends of the droplet induction pillar 140.

The eaves 130 are formed by bending at an angle from the edges of both sides of the roof 110 to the outside.

As shown in FIG. 7, the eave piece 130 is formed in a substantially plate shape and installed at a right angle with the droplet induction pillar 140, and the evaporated water supplied to the upper surface of the roof 110 is the droplet induction pillar 140. To prevent it from entering.

One side edge of the droplet induction pillar 140 may protrude along the longitudinal direction of the droplet induction pillar 140 and may further include a pillar membrane 150 that is connected to the roof barrier 120.

As shown in FIG. 9, the pillar water barrier 150 has a substantially plate shape and is installed to be substantially perpendicular to the droplet induction pillar 140.

The droplet induction pillar 140 may be installed so that the lower end portion is supported across the cooling fin 32 installed in the wet channel 30 of the heat exchanger 10.

Although not shown in the figure, a separate support jaw is formed in the partition 40 between the dry channel 20 and the wet channel 30 so that the droplet guide pillar 140 is supported or supported by the droplet guide pillar 140. It is also possible to form a support jaw to be supported by the partition wall (40).

In one embodiment of the evaporated water distribution cover 100 according to the present invention configured as described above, as shown in Figs. 10 and 11, formed at either one of the corners of the both ends of the longitudinal direction of the roof 110. And the other end of the other step is overlapped on the step of the stepped connecting jaw 116 and the other end of the roof 110 is formed on the bottom end of the other end end barrier 118 blocking the edge of the connecting jaw 116 It is also possible to comprise more.

When forming the connecting jaw 116 and the end water barrier 118 as described above, to prepare the evaporated water distribution cover 100 according to the present invention to a predetermined length and to install easily while connecting a plurality of pieces in a line in a prefabricated manner. (See FIGS. 1 and 14).

According to the evaporated water distribution cover 100 according to an embodiment of the present invention configured as described above, as shown in Figure 12, even if the inclined in such a state that the installed height of both ends are inclined to be different from each other It is possible not only to supply the low water but evenly to the whole.

That is, as shown in FIG. 13, when the evaporated water is supplied to the upper surface of the roof 110 by the evaporated water supply device 60, the evaporated water is not concentrated only at the lower side of the roof 110, but the roof barrier 120 and the pillar water barrier ( It is possible to guide the dispersion of the evaporated water to the wet channel 30 while being guided to the heat exchanger 10 by the 150 and the droplet induction column 140.

And the regeneration evaporative cooler according to the present invention, as shown in Figures 1, 2, 12, the heat exchanger 10 is provided with the dry channel 20 and the wet channel 30, and the heat exchanger 10 Including the evaporated water distribution cover 100 is formed to cover the upper end surface of the evaporated water supply device 60 for supplying the evaporated water from the upper side, and the upper end surface of the dry channel 20 of the heat exchanger (10) Is done.

The heat exchanger 10 is made of aluminum, copper, stainless steel, or the like so as to have excellent strength and thermal conductivity.

The heat exchanger 10 is installed to be formed so that the plurality of dry channels 20 and the wet channels 30 are alternately arranged in succession while being partitioned by the partition 40.

The heat exchanger 10 is installed such that the wet channel 30 is disposed between each pair of the gun channels 20 which are installed at regular intervals.

The dry channel 20 and the wet channel 30 each have a substantially rectangular cross section, and a gas flow path is installed long in a vertical or inclined direction so that a gas such as air passes therethrough.

The dry channel 20 may be formed to have a cross-sectional area of about 1 to 4 times that of the wet channel 30.

As shown in FIGS. 2 and 15, cooling fins 22 and 32 made of a material having excellent thermal conductivity, such as aluminum, copper, and stainless steel, are illustrated in the dry channel 20 and the wet channel 30. It is also possible to install each).

The cooling fins 22 and 32 are formed in a plate shape and are bent in a zigzag or wavy shape between the pair of partition walls 40 facing each other, and brazing is performed on the partition walls 40. Through welding integrally fixed.

Gas, such as air, is introduced into the dry channel 20 to lower the temperature at one side (lower side), and the introduced gas is wet channel 30 through the cooling fins 22, 32, and the partition 40. ) Is exchanged to the other side (upper side) after the temperature decreases.

The wet channel 30 is supplied with evaporated water such as water to flow through the partition 40, the cooling fin 32, and the like, and a part of the gas discharged upward through the dry channel 20 passes again. Done.

An air distribution guide 50 may be connected to the lower side of the heat exchanger 10 to allow air to flow in or out of the dry channel 20 and the wet channel 30, respectively.

The evaporated water supply device 60 is formed using a sprinkler or a spray nozzle to evenly spray evaporated water such as water on the heat exchanger (10).

The evaporated water distribution cover 100 is formed by covering the upper end surface of the dry channel 20 of the heat exchanger 10 at a predetermined interval to cover the evaporated water supplied by the evaporated water supply device 60. Guided to the wet channel (30) is formed so as to evenly wet the wet channel (30).

Since the evaporated water distribution cover 100 can be implemented in the same configuration as the embodiment of the evaporated water distribution cover 100 according to the present invention, a detailed description thereof will be omitted.

As shown in FIGS. 5 and 7, the regenerative evaporative cooler according to the present invention configured as described above has an angle between both edges of the roof 110 and the upper end surface of the gun channel 20 of the heat exchanger 10. The distance H is installed to be maintained at approximately 80% or more of the distance S1 between the partition walls 40 located on both sides of the gun channel 20.

If the distance (H) between the two edges of the roof 110 and the top end surface of the gun channel 20 is too narrow compared to the distance (S1) between the partition walls 40 located on both sides of the gun channel 20, the gun channel 20 ) To prevent the smooth flow of air flowing into the wet channel 30 and less than 70 ~ 80% of the air discharged from the dry channel 20 is not smooth.

And as shown in Figure 14 and 15, the regenerative evaporative cooler according to the present invention configured as described above, the roof (each installed above the gun channel 20 located adjacent to each other of the heat exchanger 10 ( The space D between the 110 is installed to be maintained at 50% or more of the distance S2 between the partition walls 40 on both sides of the wet channel 30.

When the distance D between the roof 110 is too smaller than the distance S2 between the partition walls 40 on both sides of the wet channel 30, the air 110 flowing into the wet channel 30 is introduced into the roof 110. The air flow is prevented from flowing smoothly and is less than 50% and the flow of air flowing into the wet channel 30 is not smooth.

10: heat exchanger 20: dry channel
30: wet channel 22, 32: cooling fin
40: bulkhead 50: air distribution guide
60: evaporated water supply device 100: evaporated water distribution cover
110: roof 111: slope
112: partition projection 116: connection jaw
118: end barrier 120: roof barrier
130: eave 140: column induction pillar
150: pillar closure

Claims (15)

A roof with a tunnel shape,
A plurality of roof barriers installed on the top surface of the roof at a predetermined interval along the longitudinal direction to protrude between the center and both edges of the roof, respectively;
It includes a plurality of droplet induction pillars are formed to be formed at regular intervals along the longitudinal direction at both corners of the roof to guide the evaporated water of the upper surface of the roof to the lower side of the roof, and to support the roof to a certain height,
The droplet induction column is disposed to correspond to the roof barrier evaporated water distribution cover. The method according to claim 1,
The roof is formed by evaporated water distribution cover is formed so as to form a "브 (reverse b)" cross-section as two slopes are connected. The method according to claim 1,
The roof cladding is disposed on both sides of the roof relative to the evaporated water distribution cover arranged in a staggered pattern. delete The method according to claim 1,
The droplet induction column is formed in a bar plate shape evaporated water distribution cover that is installed to extend in the lower side from both edges of the roof. The method according to any one of claims 1 to 3 and 5,
Evaporated water distribution cover further comprises a plurality of pillars formed to each formed to protrude along one edge of the droplet induction pillar and connected to the roof barrier. The method according to claim 1,
Evaporated water distribution cover further comprises a partition protrusion formed so as to protrude along the central portion of the roof so that the upper space of the roof is divided into two sides on the basis of the width direction central portion. The method according to claim 1,
Evaporated water distribution cover further comprises a plurality of eaves formed to be bent outwardly from both corners of the roof and positioned between the upper ends of the droplet induction pillar. The method according to claim 1,
Evaporated water distribution cover further comprises a stepped connecting jaw formed on one of the edges of both ends of the longitudinal direction of the roof and assembled with the other edge overlapping the top. The method of claim 9,
Evaporated water distribution cover is formed on the bottom surface of the other end of the roof further comprises an end blocking the edge of the connecting jaw. A heat exchanger installed and formed so that a plurality of dry channels and wet channels are partitioned by a partition and alternately arranged in succession,
An evaporative water supply device for supplying evaporated water from above the heat exchanger;
It is formed by forming a cover to cover one end surface of the dry channel of the heat exchanger at a predetermined interval, a plurality of installed to guide the evaporated water supplied by the evaporated water supply device to the wet channel and evenly wet the wet channel Including the evaporated water distribution cover,
The evaporated water distribution cover is formed in a tunnel shape and is formed to extend along one end surface of the key channel of the heat exchanger, and is disposed between the center and both edges of the roof at regular intervals along the longitudinal direction on the upper surface of the roof. A plurality of roof claddings formed to cross and protrude from each other, and a plurality of droplet induction pillars formed by inducing evaporated water from the upper surface of the roof to the wet channel and having a predetermined interval along the longitudinal direction at both edges of the roof. Regenerative evaporative cooler comprising a. The method of claim 11,
The roof of the evaporated water dispensing cover is formed by installing two inclined surfaces to form a cross-sectional shape of "∧ (reverse V)."
The roof clasps are arranged in a staggered pattern on two inclined surfaces of the roof,
The droplet induction pillar is disposed in correspondence with the roof cladding. The method of claim 11,
The evaporated water distribution cover is formed to protrude along one edge of the droplet induction pillar, respectively, and is provided with a plurality of pillar membranes connected to the roof barrier, and are bent outwardly from both edges of the roof and the droplet induction pillar. Regenerative evaporative cooler further comprising a plurality of eaves respectively installed to be positioned between the upper ends of the. The method of claim 11,
And the evaporated water distribution cover is installed such that each distance between both edges of the roof and the upper end of the key channel of the heat exchanger is maintained at 80% or more of the distance between the partition walls located at both sides of the gun channel. The method of claim 11,
A pair of evaporated water distribution covers respectively installed above the dry channel located adjacent to each other of the heat exchanger may be formed and installed so that the space between the roofs is maintained at 50% or more of the distance between the partition walls on both sides of the wet channel. Chiller.

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