KR200307257Y1 - air conditioning system - Google Patents

Abstract

The air conditioning system of the present invention is composed of a cooling coil 11, a blower 13, and a perfect catcher 15 in order to maximize the condensate blocking effect to efficiently collect and discharge the condensate generated around the cooling coil. The perfect catcher 15 is provided at equal intervals on opposite inner sides of the upper and lower base plates 17 and 19 and the upper and lower base plates provided in opposite positions, and the upper and lower ends are fixedly mounted to each other. A plurality of protruding corrugations 33, 45, drain channels 35, 41, 47, 51, and horizontal space protrusions on the inner and outer surfaces which are curved in a curved state so as to extend in the vertical direction to form a curved air passage c. (39, 49) and the front, rear and a plurality of inner blades (21, 23, 25) having one or more screw fastenings (37, 43, 53).

Description

Air conditioning system

The present invention relates to an air conditioning system, and more particularly, to an air conditioning system for efficiently collecting and discharging condensate generated around a cooling coil during heat exchange.

The air conditioning system is equipped with a cooling coil as a heat exchange means. At the surface of the cooling coil, airflow and heat exchange are performed due to the wind pressure of the blower, and moisture contained in the air condenses and flows down the surface of the cooling coil. This condensate is scattered by the wind pressure of the blower and flows into the air passage through the blower.

An eliminator 1 as shown in FIG. 1 is installed between the cooling coil and the blower to collect the condensate and block the inflow.

The eliminator 1 consists of a front cover 3 and a rear cover 5 and a plurality of blades 7 arranged at regular intervals between the two covers 3 and 5.

However, since the eliminator 1 is formed in a zigzag state in which the blade 7 has a straight inclined surface, it is difficult to completely collect the condensed water 9 scattered by the wind pressure of the blower.

In addition, the eliminator 1 further reduces the condensate trapping power when the wind speed of the blower is high, and the differential pressure inside and outside the air conditioning system increases when the air volume is reduced by using a damper to prevent the drop of the condensate collecting power. It has the disadvantage of making it difficult to discharge condensate.

Therefore, the present invention is to solve the above points, the object of the present invention is to provide an air conditioning system to efficiently collect and discharge the condensate generated around the cooling coil to maximize the condensate blocking effect.

This air conditioning system is a cooling coil that circulates a refrigerant to exchange heat.

A blower that creates airflow around the cooling coil for continuous heat exchange of the cooling coil,

A perfect catcher is provided between the cooling coil and the blower to prevent condensate generated in the cooling coil from being scattered to the blower side due to the wind pressure of the blower.

The perfect catcher is disposed at equal intervals between the upper and lower base plates provided in parallel to the upper and lower postures, and the upper and lower base plates, and the upper and lower bases are fixedly mounted to each other so that the upper and lower base plates are fixed to each other. It consists of the front, rear, and a plurality of inner blades that extend in the vertical direction to form an air passage.

The front and rear blades form the front and rear sides of the air passage at the front and rear sides of the perfect catcher, respectively.

The front blade has a plurality of protruding corrugations extending vertically and vertically with respect to the air flow on the curved inner surface and the front side of the inclined surface, and having a drain channel extending in parallel with the protruding corrugations behind the inclined surface. It has a number of screw fasteners extending parallel to the corrugation and drain channels.

The rear blade has a horizontal space protrusion which protrudes into an air passage on a curved curved surface and opens the air inlet side, and a screw fastening portion where the set screw is fastened to the drain channel and horizontal space protrusion extending in the same direction as the horizontal space protrusion. Equipped.

In addition, the inner blade has both the front and rear blade structures because of its installation position.

That is, the inner blade has a protruding pleat and drain channel having the same structure as the front blade on the curved inner surface, and the horizontal space protrusion protruding into the air passage on the curved outer surface to open the air inlet side. And a drain channel extending in the same direction as the horizontal space protrusion and a screw fastening portion for fastening the set screw to the horizontal space protrusion.

As described above, the air conditioning system according to the present invention is curved in a perfect catcher installed between a cooling coil and a blower in a curved state, and includes front, rear, and protrusion protrusions, drain channels, horizontal space protrusions, and screw joints on its inner or outer surfaces. The inner blades are formed on the upper and lower base plates in a redundant structure to efficiently collect and discharge condensate generated around the cooling coils.

1 is a plan view of the operating state to block the scattering of condensate in the eliminator used in the air conditioning system according to the prior art.

2 is a perspective view of an air conditioning system according to the present invention.

3 is an exploded perspective cross-sectional view of the perfect catcher used in the air conditioning system of FIG.

4 is a plan view of an operating state that blocks the condensate from scattering in the perfect catcher of FIG.

* Description of the symbols for the main parts of the drawings *

11: cooling coil 13: blower

15: perfect catcher 17, 19: upper and lower base plate

21, 23, 25: before, after, inner blade 27: drain hole

29: set screw 31: fastener

33, 45: protrusion pleat 35, 41, 47, 51: drain channel

37, 43, 53: screw fastening part 39, 49: horizontal space protrusion

a: condensate b: air flow

c: air passage

Advantages and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

2 is a perspective view of an air conditioning system according to the present invention, which includes a cooling coil 11, a blower 13, and a perfect catcher 15. The air conditioning system causes heat exchange in the cooling coil 11 by circulating a refrigerant in the cooling coil 11, and supplies the air cooled by the heat exchange action to the air passage under the air pressure of the blower 13, and at this time, the cooling The condensed water a condensed on the surface of the coil 11 is collected by the perfect catcher 15 provided between the cooling coil 11 and the blower 13 and discharged outside.

The perfect catcher 15 completely collects and discharges the condensed water a generated in the cooling coil 11 without disturbing the air flow due to the wind pressure of the blower 13 to the blower 13 and the blower 13. It blocks the inflow of condensate (a) into the air passages to be connected.

As shown in FIG. 3, the perfect catcher 15 is formed between the upper and lower base plates 17 and 19 and upper and lower base plates 17 and 19. It consists of the front, rear, and inner blades 21, 23, and 25 which are installed in a horizontal state to form a curved air passage in duplicate.

The upper and lower base plates 17 and 19 define both sides of the air passage formed in the interior of the perfect catcher 15 by the front, rear and inner blades 21, 23, and 25, and condensate ( A plurality of drain holes 27 for discharging a) are provided. The front, rear and inner blades (21, 23, 25) is installed between the upper and lower base plates (17, 19) in its own bent state twice to form an air passage of a redundant structure bent in a snake shape have. The front, rear and inner blades 21, 23, 25 may be bent not only twice but also once or three times as needed.

The upper and lower base plates 17 and 19 form upper and lower outer edges of the perfect catcher 15, and the front, rear and inner blades 21, 23 and 25 are fixedly installed. That is, the upper and lower base plates 17 and 19 are provided with a plurality of fasteners 31 to fasten the front, rear and inner blades 21, 23 and 25 with the set screw 29. The fasteners 31 are upper and lower base plates 17 and 19 corresponding to the arrangement intervals of the front, rear and inner blades 21, 23 and 25 installed between the upper and lower base plates 17 and 19. It is formed in.

The front, rear and inner blades 21, 23, and 25 installed between the upper and lower base plates 17 and 19 are disposed at equal intervals between the upper and lower base plates 17 and 9, respectively. It is fastened to the upper and lower base plates 17 and 19 at the rear end. Therefore, neighboring front, rear and inner blades (21, 23, 25) to form a horizontal space while forming a snake-like air passage by the second bend itself.

The front and rear blades 21 and 23 may be provided at the front and rear sides of the perfect catcher 15 to form the same structure as the front and rear sides of the perfect catcher 15, but may have the same structure. Each of them is formed differently.

That is, the front blade 21 forms one side of the air passage of the same structure as its inner surface, that is, the front side of the foremost air passage, and the rear blade 23 has one side of the air passage of the same structure as its outer surface, that is, the rear side. The rear side of the air passage is formed, respectively. The inner blade 25 is bent in the same shape as the inner surface of the front blade 21 and the outer surface of the rear blade 23, and the front and rear blades 21 and 23 are opposite to the front and rear blades 21 and 23. Together, the other side of the air passage is formed, and on the opposite side of the other inner blade 25 which is continuous, one side of the other air passage is formed together with the inner blade 25.

When the inner blade 25 of this structure is provided at equal intervals between the front and rear blades 21 and 23, the perfect catcher 15 is provided with the air passages of the same interval in duplicate.

Since the front, rear and inner blades 21, 23, and 25 are formed with the curved inner surface or the outer surface twice in the direction of the air flow (b), even if the air passes once without interfering with the air flow, The condensate (a) contained in can be efficiently collected and removed.

In order to efficiently collect the condensate (a) in this way, the front blade 21 is provided with protruding wrinkles 33 on the curved inner surface and the inclined surface front side to collect the condensate (a) contained in the air passing through the air passage. Doing. The protruding wrinkles 33 extend in the height direction (Fig. 3, the up and down direction of the perfect catcher) while being perpendicular to the air flow a so as to form the condensate a as water droplets.

In addition, the front blade 21 has a drain channel 35 extending in the same direction as the protruding corrugation 33 on the rear side of the inclined surface. The drain channel 35 is formed by the condensed water a impinging on the protruding corrugations 33 and guides the water droplets falling down the slope to the drain holes 27 of the upper and lower base plates 17 and 19 to be discharged. To be.

The front blade 21 is provided with a plurality of screw fastening portions 37. The screw fastening portion 37, like the protruding corrugation 33 and the drain channel 35, fastens the front blade 21 with the set screw 29 between the upper and lower base plates 17 and 19, so that the air flow ( It is extended in the vertical direction (up and down direction of the perfect catcher in Fig. 3) while being perpendicular to b).

The protruding corrugations 33, the drain panel 35, and the screw fastening portions 37 are formed in the same direction as the vertical direction with respect to the air flow a, that is, the front blades ( 21 cuts the injection molded long member into an appropriate length so that it can be applied to the front side of the perfect catcher 15. The cut length of this front blade 21 defines the height of the air passage formed in the perfect catcher 15.

The rear blade 23 forms its outer surface the same as the outer surface of the inner blade 25, and cuts an elongated member, such as the front blade 21, by injection molding into an appropriate length to be applied to the rear side of the perfect catcher 15. To be able. That is, the rear blade 23 protrudes in the horizontal direction to the air passage on the curved surface curved in the horizontal direction, the horizontal space protrusion 39 formed to open the air inlet side and the drain extending in the same direction as the horizontal space protrusion 39 The channel 41 and the screw fastening part 43 formed in this horizontal space protrusion 39 are provided. The horizontal space projecting portion 39, the drain channel 41, and the screw fastening portion 43 extend in the vertical direction (up and down direction of the perfect catcher in FIG. 3).

Since the plurality of inner blades 25 installed between the front and rear blades 21 and 23 are bent to have the same shape as the inner surface of the front blade 21 and the outer surface of the rear blade 23, the front and rear blades are formed. (21, 23) The opposite side forms the other side of the air passage together with the front and rear blades 21, 23, and the other side of the air passage together with the other inner blade 27 on the opposite side of the other inner blade 25, which is continuous. To form one side of the. When the inner blade 25 of such a structure is installed at equal intervals between the front and rear blades 21 and 23, the air catchers having the same interval are formed in the perfect catcher 15 in an overlapping manner.

The curved inner surface of the inner blade 25 is provided with a projecting corrugation 45 and a drain channel 47 having the same structure as the curved inner surface of the front blade 21 as shown in FIG. The protruding pleats 45 and the drain channel 47 are configured and function in the same manner as the protruding pleats 33 and the drain channel 37 formed on the curved inner surface of the front blade 21.

In addition, the inner blade 25 forms both sides of adjacent air passages, unlike the front and rear blades 21 and 23 forming the outside of the perfect catcher 15, so that the inner blade 25 is not only curved inside but also curved outside. The horizontal space protrusion 49 and the drain channel 51 are further provided.

This horizontal space protrusion 49 projects in the curved outer surface to capture condensate a from the air passing through the air passage formed in the perfect catcher 15 so as to act as a substantial resistance to the air flow (b) direction. The inlet side is open and the outlet side is closed. In addition, the drain channel 51 provided on the outer surface of the inner blade 25 extends in the same direction as the horizontal space protrusion 39 to collect the droplets of condensate (a) falling from the air passage and discharge it to the drain hole 27. .

The inner blade 25 has a horizontal space protrusion 49 to fasten and fix the fastener 31 of the upper and lower base plates 17 and 19 like the front and rear blades 21 and 23 with the set screw 29. ), A screw coupling portion 53 is provided.

When the front, rear and inner blades 21, 23, 25 configured as described above are installed between the upper and lower base plates 17, 19, the air passage as shown in FIG. 3 is perfect catcher 15. It is formed in the overlapping. FIG. 4 illustrates an air passage c that is bent by two neighboring inner blades 25, 25. This convex air passage (c) makes the flow of air natural, so that the pressure difference acting inside and outside the air conditioning system in the process of collecting the condensate (a) is low, and the condensate ( Enable collection of a).

When the air containing the condensate (a) is introduced into the perfect catcher 15 by the drive of the blower 13 passes through the air passage (c) bent in a snake shape. The air passing through the air passage c hits the projecting corrugations 45 formed on the inclined surfaces and the curved inner surfaces of the two adjacent inner blades 25 and 25. At this time, the condensate (a) contained in the air is heavier than the air is condensed into a drop to fall down. The condensate (a) droplets are collected in the drain channels 47 and 51 of the inner blade 25 and discharged into the drain holes 27 of the upper and lower base plates 17 and 19. At the same time, the air passing through the air passage c hits the horizontal space protrusion 53 formed on the curved outer surfaces of two adjacent inner blades 25 and 25. At this time, the condensate (a) contained in the air is heavier than the air, so that the condensate into the droplets do not return to the horizontal space projecting portion 49 is discharged to the drain channels (47, 51).

As described above, the air conditioning system according to the present invention installs a perfect catcher between the cooling coil and the blower, and curves the perfect catcher in a curved state, and has a front pleat and a drain channel and a horizontal space protrusion on its inner or outer surface. Ellie with blades bent in a zigzag shape on a straight slope by effectively forming a redundant structure by the rear and inner blades, effectively blocking the condensed water scattered by the wind pressure of the blower and reducing the differential pressure acting inside and outside the air conditioning system. Compared with the prior art using a miner, the condensate generated around the cooling coil can be efficiently collected and discharged, and the condensate collecting power can be further enhanced when the wind speed of the blower is fast.

Claims (1)

An air conditioning system comprising a cooling coil that performs heat exchange, a blower that forms an air stream for heat exchange of the cooling coil, and a perfect catcher that collects condensate generated in the cooling coil by the air flow of the blower. The perfect catcher 15 includes upper and lower base plates 17 and 19 provided in opposite positions; It is provided at equally spaced heights on opposite inner sides of the upper and lower base plates, and is fixedly mounted on the upper and lower ends thereof, and extends in the horizontal space and the vertical direction to form curved air passages c. Blades 21, 23, 25, The front blade 21 has a plurality of protruding corrugations 33 formed at the front side of the inclined surface and the curved inner surface, a drain channel 35 extending parallel to the protruding corrugation at the rear side of the inclined surface, the protruding corrugation and the drain channel and It includes a plurality of screw fastening portion 37 formed in parallel, The rear blade 23 protrudes into an air passage on an outer surface curved in a curved state, and a horizontal space protrusion 39 having an air inlet side open, a drain channel 41 extending in the same direction as the horizontal space protrusion, this horizontal It includes a screw fastening portion 43 formed in the space protrusion, The inner blade 25 is protruded corrugation 45 formed on the front side of the curved surface and the inclined surface and the drain channel 47 formed on the rear side of the inclined surface, protruding through the air passage on the curved surface A horizontal space protrusion (49) with an air inlet side open, a drain channel (51) extending in the same direction as the horizontal space protrusion, and a screw fastening portion (53) formed in the horizontal space protrusion.