KR101207551B1 - Recyling Evaporation Cooler - Google Patents

Abstract

Since the guide member can be easily connected to the heat exchanger body, assembling properties are improved and the same shape of the guide member is used to connect and reduce the manufacturing cost, the plurality of gun channels and wet channels are alternately arranged alternately while being partitioned by the partition wall. A plurality of guide members connected to each other and connected to each other and guiding air to flow into or out of the dry and wet channels of the heat exchanger body, and fixedly installed at the ends of the dry and wet channels of the heat exchanger body. Provided is a regenerative evaporative cooler comprising a plurality of support members for supporting the heat exchange body.

Description

Recyling Evaporation Cooler

The present invention relates to a regenerative evaporative cooler, and more particularly, a regenerative evaporative cooler configured to easily and easily connect and install a guide member for guiding air into or out of a dry channel and a wet channel to a heat exchanger body. It is about.

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. Compressor for compressing the high temperature and high pressure of the vapor state, 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, a regenerative evaporative cooling ventilator and the like have recently been developed to improve such a problem.

Conventional regenerative evaporative cooling ventilation device is configured to install a regenerative evaporative cooler on the ventilation passage made of a duct so as to reduce the ventilation load through the sensible and latent heat transfer between the indoor exhaust and the outdoor intake air.

The regenerative evaporative cooler, which is a key component of the regenerative evaporative cooling ventilator, has a heat exchanger body which is alternately arranged while the dry channel and the wet channel are partitioned by partition walls, and connected to the heat exchanger body and air flows into the dry channel and the wet channel. It is composed of a guide member for guiding the discharge or spillage.

The outdoor air is sucked into the dry channel, and a part of the sucked air is added to the wet channel.

When water is supplied to the wet channel by the water supply unit, the bleed air of the wet channel is cooled by evaporation of the water, and the cooled bleed air takes heat from the intake air passing through the dry channel to lower the temperature of the intake air.

In the conventional regenerative evaporative cooler configured as described above, the aspect of improvement of the productivity and assemblability of the parts is one of the very important parts in order to favor the commercialization together with the efforts to improve the heat exchange efficiency. to be.

An object of the present invention is made in view of the above point, as the guide member for guiding the air flow into or out of the dry channel and the wet channel is made of a structure that can be easily and easily connected to the heat exchange body assemblability The purpose is to provide a regenerative evaporative cooler that is improved.

Another object of the present invention is to provide a regenerative evaporative cooler capable of reducing the manufacturing cost and the cost of parts replacement, etc., by connecting and using a plurality of identically shaped guide members.

The regenerative evaporative cooler proposed by the present invention is provided with a heat exchanger body in which a plurality of dry channels and wet channels are alternately arranged while being partitioned by partition walls, and are connected to each other, and air flows into the dry and wet channels of the heat exchanger body, respectively. It comprises a plurality of guide members for guiding to flow out, and a plurality of support members fixed to the heat exchange body and for supporting the guide member on the heat exchange body.

Cooling fins formed in a plate shape and bent in a zig-zag are respectively installed in the wet channel and the dry channel of the heat exchanger body.

The guide member has a pair of body portions formed by being bent at right angles toward the gun channel at one side edge of the body portion and the body portion which are formed to be formed so that one side is opened in a state surrounding the end side of the wet channel. It consists of an extension.

A plurality of assembly protrusions are formed in the body portion of the guide member.

In addition, the body portion of the guide member may be further formed with a pair of stepped projections that are in close contact with each of the edge of the support portion of the support member.

In addition, the body portion of the guide member may be further formed with a plurality of gap maintaining pieces for maintaining the gap with the guide member located adjacent to each other.

The gap retaining piece is installed such that the gap retaining piece formed on the guide member positioned adjacent to the edge portion is in contact with each other.

The extension of the guide member is installed so as to block one side around the end of the gun channel located between the body portion of the guide member is located adjacent to the extension and the edge of the guide member is located adjacent to each other is connected to each other .

The support member is formed by extending each of the partition wall end side of the heat exchanger body and integrally fixed to the partition wall and installing a band-shaped support unit to which the body of the guide member is connected.

The support portion of the support member is formed with a plurality of assembling holes for assembling the assembly projection of the guide member.

According to the regenerative evaporative cooler according to the present invention, the guide member for guiding the air into or out of the dry channel and the wet channel is easily and easily assembled and installed on the heat exchanger body using a support member, thereby improving workability and parts. Easy maintenance such as replacement.

In addition, according to the regenerative evaporative cooler according to the present invention, the assembling holes of the guide member and the assembling holes of the support member are assembled and connected to each other.

In addition, according to the regenerative evaporative cooler according to the present invention, since the adhesion between the guide member and the support member is improved by providing the guide member with a spacing member, it is possible to maintain excellent airtightness between the dry channel and the wet channel.

Furthermore, according to the regenerative evaporative cooler according to the present invention, since the guide member is made of the same shape and is used in a plurality of consecutive installations, it is possible to reduce manufacturing costs such as mold costs and to improve productivity.

1 is a perspective view showing an embodiment of a regenerative evaporative cooler according to the present invention.
2 is an exploded perspective view showing an embodiment of a regenerative evaporative cooler according to the present invention.
3 is an enlarged exploded perspective view showing an embodiment of a regenerative evaporative cooler according to the present invention.
4 is a front view showing an embodiment of the regenerative evaporative cooler according to the present invention.
5 is a side view showing an embodiment of a regenerative evaporative cooler according to the present invention.
Figure 6 is a plan view showing a heat exchange body in one embodiment of the regenerative evaporative cooler according to the present invention.
7 is a perspective view showing a guide member in one embodiment of the regenerative evaporative cooler according to the present invention.
8 is a perspective view showing a support member in an embodiment of the regenerative evaporative cooler according to the present invention.
9 is a cross-sectional view taken along the line AA of FIG. 4.
10 is a cross-sectional view taken along line BB of FIG. 5.
11 is a cross-sectional view separating the guide member and the support member in one embodiment of the regenerative evaporative cooler according to the present invention.
Figure 12 is an enlarged cross-sectional view showing the extension of the guide member in one embodiment of the regenerative evaporative cooler according to the present invention.
Figure 13 is a perspective view of the finishing support member in one embodiment of the regenerative evaporative cooler according to the present invention.
14 is a cross-sectional view showing the finishing support member in one embodiment of the regenerative evaporative cooler according to the present invention.
15 is a perspective view showing a state in which a plurality of embodiments of the regenerative evaporative cooler according to the present invention are manufactured to a predetermined standard and connected to each other.

A preferred embodiment of the regenerative evaporative cooler according to the present invention will be described in detail with reference to the drawings.

First, an embodiment of the regenerative evaporative cooler according to the present invention, as shown in Figures 1 to 5, the plurality of dry channels 20 and the wet channel 30 are alternately arranged alternately while being partitioned by the partition wall (40). A plurality of guide members 50 connected to the heat exchanger body 10 and guided to allow the air to flow in or out of the dry channel 20 and the wet channel 30 of the heat exchanger body 10, respectively; It is integrally fixed to the heat exchange body 10 and comprises a plurality of support members 60 for supporting the guide member 50 to the heat exchange body (10).

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

As shown in FIG. 6, the heat exchange body 10 is disposed such that the wet channel 30 is positioned between each pair of the dry channel 20 installed at regular intervals.

The dry channel 20 may be formed to be about 1.5 to 3 times wider than the wet channel 30.

Inside the dry channel 20 and the wet channel 30 is made of aluminum, copper, stainless steel, etc. using a material having excellent thermal conductivity and made of a plate-like cooling pin 22 is bent in a zigzag form, It is also possible to install 32 in the state which is integrally welded and fixed to the said partition 40 through brazing etc., respectively.

Although not shown in the drawing, the air having a lower temperature is discharged to the indoor side as heat is exchanged with the wet channel 30 after the air of the outdoor side is introduced into the dry channel 20, and the wet channel 30 is discharged to the indoor side. Water is supplied to flow through the partition 40, the cooling fin 33, and the like, and a part of the air discharged to the indoor side through the gun channel 20 is discharged to the outdoor side.

The guide member 50 is made of synthetic resin, such as transparent or opaque, translucent, and one end portion of the dry channel 20 and the wet channel 30 of the heat exchanger body 10 through the support member 60. Although connected to the end, and not shown in the figure, it is also possible to be connected to both ends of the gun channel 20 and the wet channel (30).

As shown in FIGS. 7 and 9 to 11, one side of the guide member 50 is opened in a state in which the guide member 50 is wrapped around an end side where air (extracted air) is introduced from the indoor side of the wet channel 30. It consists of a body portion 51 is formed and installed so as to be bent at a right angle toward the gun channel 20 from the corner of the opening of the body portion 51, each extending portion 56 is formed.

The body 51 has a flat, substantially triangular tubular shape, and one side is opened to communicate with the outside, and the other side is opened to communicate with the wet channel 30.

A plurality of assembling protrusions 52 are formed at the end portions of the body portion 51 that are connected to the support member 60 at regular intervals.

At the end portion of the body portion 51 connected to the support member 60, a plurality of plate-shaped spacing retaining portions 54 are formed to maintain a constant distance from the guide member 50 located next to each other. It is also possible.

In addition, the body 51 may be further provided with a pair of stepped protrusions 55 formed to be in close contact with the edge of the support member 60.

In the above, the gap retaining piece 54 is installed such that the gap retaining piece 54 formed at the body portion 51 of the guide member 50 located adjacent to each other and the edge of the end portion contact each other.

The extension part 56 is positioned between the body part 51 of the guide member 50 which is located adjacent to each other as the extension part 56 and the edge of the guide member 50 which is located adjacent to each other and abuts and connected to each other. It is installed so as to obstruct one side around the end side of the gun channel 20.

As the extension part 56 blocks one side of the periphery of the gun channel 20, the periphery of the key channel 20 is defined by the pair of body parts 51 and the extension part 56. As the surface is enclosed, it is possible to guide the air flowing in or out of the wet channel 30 in a different direction.

As shown in FIG. 12, the stepped steps 57 and 58 of the extension part 56 are engaged with the ends of the extension part 56 of the guide member 50 located next to each other. It is possible to form each and improve the airtightness between the extension parts 56. That is, the first stepped portion 57 is formed in the extension part 56 located at one side, and the second stepped portion 58 is formed in the extension part 56 located at the other side so as to correspond to the first stepped step 57. It is possible to be.

Like the heat exchanger body 10, the support member 60 is made of a material having good strength, such as aluminum and copper, and excellent thermal conductivity, and is integrally welded and fixed to the heat exchanger body 10 by brazing.

The support member 60 is installed at each end of the partition wall 40 of the heat exchanger body 10 and is integrally fixed to the partition wall 40, and one end of the body part 51 of the guide member 50 overlaps. An approximately belt-shaped support portion 61 to be connected is formed and installed.

As illustrated in FIGS. 8 to 11, the supporting member 60 extends toward the end of the partition wall 40 on both sides of the wet channel 30 of the heat exchanger body 10 and is integrally fixed to the partition wall 40. It is possible to be composed of a plurality of connecting portions 64 for connecting at a predetermined interval between the pair of the support portion 61 and the support portion 61.

The supporting portion 61 is formed with a plurality of assembly holes 62 at regular intervals so that the assembly protrusion 52 formed in the body portion 51 of the guide member 50 is assembled.

The end edge of the support 61 is in close contact with the stepped protrusion 55 formed on the body 51 of the guide member 50.

The support member 60 is formed by bending at a right angle toward the heat exchange body 10 from a pair of connecting portions 64 positioned at both ends thereof, and having a pair of plate-shaped fixed integrally to the heat exchange body 10. It is also possible to form the fixing part 66 further.

In the regenerative evaporative cooler according to the embodiment of the present invention configured as described above, as shown in FIGS. 13 and 14, the pair of gun channels 20 which are located at the edge of the heat exchange body 11 are integrally formed. It is also possible to further comprise a finishing support member 70 fixed and connected to support the guide member 50 to the soft-changing body 10 together with the support member 60.

The finishing support member 70 is installed extending from the end side of the partition wall 40 located on one side located between the gun channel 20 and the wet channel 30 located at the edge end of the heat exchange body (10) It is formed integrally with the end of the gun channel 20 which is formed in the band-shaped finishing support portion 71 fixed to the partition wall 40 and the "c" shape and located at the edge end of the heat exchange body 10, Both ends are made of a finishing fixing portion 74 connected to both ends of the finishing support (71).

The finishing support part 71 is formed with a plurality of assembly holes 72 so that the assembly protrusion 52 formed in the body portion 52 of the guide member 50 is assembled.

The finishing support part 71 of the finishing support member 70 is formed of the guide member 50 located at the edge end of the heat exchange body 10 together with the supporting part 61 located at one side of the supporting member 60. The body 51 is connected to and supported by the soft exchange body 10. That is, the guide member 50 positioned at the edge end of the heat exchanger body 10 has a body portion 51 positioned at one end of the finish supporting member 71 and the supporting member 60 of the finishing supporting member 70. It is installed between the support portion 61 is connected to the heat exchange body (10).

As shown in FIG. 13, the regenerative evaporative cooler according to the present invention configured as described above may produce the heat exchange body 10 in a rectangular cylindrical shape having a predetermined size, and a plurality of heat exchange bodies 10 in the transverse direction depending on the processing scale. It is also possible to install and use one after another.

In the above, a preferred embodiment of the regenerative evaporative cooler according to the present invention has been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. This also belongs to the scope of the present invention.

10: heat exchanger body 20: dry channel
30: wet channel 22, 32: cooling fin
40: partition 50: guide member
51: body 52: assembly protrusion
54: interval maintenance 55: step projection
56: extension 57, 58: step
60: support member 61: support
62, 72: assembly hole 64: connection portion
66: fixing part 70: finishing support member
74: deadline

Claims (5)

A heat exchange body in which a plurality of dry channels and wet channels are partitioned by partition walls and alternately arranged alternately;
A plurality of guide members connected to each other and guided to allow air to flow into or out of the dry channel and the wet channel of the heat exchanger body;
It is fixed to the heat exchange body and includes a plurality of support members for supporting the guide member on the heat exchange body,
The guide member has a pair of body portions formed by being bent at right angles toward the gun channel at one side edge of the body portion and the body portion which are formed to be formed so that one side is opened in a state surrounding the end side of the wet channel. Consisting of extensions,
The extension of the guide member is installed so as to intersect one side around the end of the gun channel end located between the body portion of the guide member is located adjacent to the extension and the edge of the guide member is located adjacent to each other and connected ,
The support members are respectively provided extending to the partition wall end side of the heat exchanger body and are integrally fixed to the partition wall and are provided by a band-shaped support portion to which the body portion of the guide member is connected.
The support portion of the support member further forms a plurality of assembly holes at regular intervals,
The body portion of the guide member is further formed with a plurality of spacing retaining pieces for maintaining a distance between the plurality of assembling protrusions and the guide member located adjacent to each other, the assembling holes,
The gap retaining piece is a regenerative evaporative cooler installed so that the gap retaining piece formed on the guide member located adjacent to each other and the end edges abut each other. The method according to claim 1,
Regenerative evaporative cooler to the body portion of the guide member to form and install a pair of stepped projections that are respectively in close contact with the edge of the end of the support of the support member. The method according to claim 1,
The support member is a regenerative evaporative cooler comprising a plurality of connecting portions which are installed at both ends of the partition walls on both sides of the wet channel of the heat exchanger body and connect a pair of the support portions fixed to the partition walls at regular intervals. The method according to claim 3,
And a pair of plate-shaped fixing parts formed at both ends of the support member at right angles to the heat exchange body at the connection part and fixed integrally to the heat exchange body. The method according to claim 1,
An evaporative cooler further comprising cooling fins each formed in a plate shape and bent in a zigzag form in the wet channel and the dry channel of the heat exchanger body.

Images