JP2016156565A - Cooling device and cooling method of heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling device of a heat exchanger having a high cooling efficiency.SOLUTION: When a fan 4 of an outdoor unit 1 is actuated, an airflow passing through an opening 25 of buffer means 20 for wind is guided from an outdoor air intake port 5 to a heat exchanger 3. When processed water having the electric conductivity less than 20 μS/cm is sprayed from a sprinkler nozzle 12 to the outdoor air intake port 5, the processed water is delivered with the airflow, cooling the heat exchanger 3.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling device for a heat exchanger provided in an outdoor unit of a cooling device and a cooling method for the heat exchanger using the cooling device.

  The cooling device includes a combination of an indoor unit and an outdoor unit for radiating heat from the room to the outside. The outdoor unit includes a heat exchanger for radiating heat.

Patent Document 1 describes a heat exchanger cooling method for preventing power saving and scale generation by spraying treated water having a low electrical conductivity treated by a reverse osmosis membrane device to the heat exchanger. ing.
Patent Document 2 describes a heat exchanger cooling device that prevents power generation and scale generation by sprinkling treated water with low electrical conductivity treated by a reverse osmosis membrane device to the heat exchanger. ing.
Patent Document 3 uses heat treated with activated sludge from factory effluent as raw water, and water that has been purified from the raw water is sprayed on the heat exchanger to prevent power saving and scale generation. A method for cooling the exchanger is described.

JP 2010-243144 A JP 2012-177539 A JP 2012-112565 A

  The present invention relates to a heat exchanger that can increase the cooling efficiency when sprinkling treated water with low electrical conductivity treated by a reverse osmosis membrane device with respect to a heat exchanger provided in an outdoor unit of a cooling device. It is an object of the present invention to provide a cooling device and a cooling method for a heat exchanger using the cooling device.

The present invention provides a cooling device for the heat exchanger in an outdoor unit including a heat exchanger, a fan, a condenser, and a compressor for taking outside air from the outside air intake port, blowing the air to the heat exchanger, and cooling the air. It has watering means and wind buffer means,
The watering means is
It has a reverse osmosis membrane device for obtaining treated water having an electrical conductivity of less than 20 μS / cm, a water pipe for feeding the treated water, and a watering nozzle for sprinkling the treated water. The watering nozzle is arranged on the surface side including the outside air intake port,
The wind buffer means is
It is a member having a wind shielding surface having an opening, and the total area of the opening with respect to the area of the shielding surface (area including the opening) is in the range of 5 to 60%,
The shielding surface having the opening is arranged at a distance from the surface including the outside air intake port,
When the fan of the outdoor unit is activated, outside air passes through the opening of the wind buffer means, is taken in from the outside air intake, and is blown to the heat exchanger,
The position of the opening of the wind buffer means and the position of the watering nozzle are adjusted so that the watering nozzle is positioned in the air flow from the opening to the outside air intake. And a method for cooling a heat exchanger using the cooling device.

The heat exchanger cooling device of the present invention and the heat exchanger cooling method using the cooling device heat the treated water of the reverse osmosis membrane device together with the air flow by utilizing a wind buffer means having an opening. It is characterized by spraying on the exchanger.
The wind buffer means having the opening suppresses the influence of the wind on the spray of the treated water of the reverse osmosis membrane device, forms an airflow flowing toward the heat exchanger through the opening, and is sprayed. Cooling efficiency can be improved by making treated water and a heat exchanger easy to contact.
Increasing the cooling efficiency means that when the same amount of water is used, the amount of treated water that is not used for cooling the heat exchanger is reduced compared to the case where the wind buffer means is not used, and the effect of reducing the amount of electricity used is reduced. It means to grow.
Further, increasing the cooling efficiency means that the amount of water to be sprayed can be reduced when an effect of reducing the amount of electricity used is the same as when the wind buffering means is not used.

  According to the heat exchanger cooling device and the heat exchanger cooling method using the cooling device of the present invention, a stable power consumption reduction effect can be obtained regardless of the installation environment of the outdoor unit.

Sectional drawing of the height direction seen from the side surface side of the cooling device of the heat exchanger of this invention. The perspective view of the cooling device of the heat exchanger of FIG. 1 (however, the cooling means is omitted). The perspective view of the cooling device of the heat exchanger which is embodiment different from FIG. 1 (however, the cooling means is abbreviate | omitted). (A)-(h) is a top view of the cooling device of the heat exchanger of this invention. However, water spraying means are omitted in (b) to (h). (A), (b) is a front view of the wind buffer means used with the cooling device of the heat exchanger of this invention. (A)-(d) is height direction sectional drawing of the buffer means of the wind used with the cooling device of the heat exchanger of this invention. (A)-(d) is height direction sectional drawing of the cushioning means of the wind which is an embodiment different from the thing of FIG. 6 used with the cooling device of the heat exchanger of this invention. The perspective view of the wind buffer means which is further another embodiment used with the cooling device of the heat exchanger of this invention. (A) is height direction sectional drawing of the wind buffer means of FIG. 8, (b), (c) is height direction sectional drawing of embodiment different from (a).

<Cooling device for heat exchanger>
(1) Cooling device for heat exchanger in FIGS. 1 and 2 The cooling device for the heat exchanger will be described with reference to FIGS.
In the outdoor unit 1 of the cooling device, a heat exchanger 3 and a fan 4 are disposed in a housing 2. Other components such as a condenser, a compressor, and a pipe are omitted.
On one side of the housing 2, an outside air intake 5 is provided. In the embodiment of FIG. 1, the outside air intake 5 is formed only on one surface side, but may be formed on two surfaces or three or more surfaces.

The watering means 10 has a reverse osmosis membrane device (not shown), a water supply pipe 11 for supplying treated water by the reverse osmosis membrane device, and a watering nozzle 12 for watering the treated water.
The reverse osmosis membrane device is connected to a water source (not shown). If there is a water intake, the water source may be used, or if it is a building, a water storage tank installed on the roof may be used. You may utilize the treated water which processed the waste water. The water source itself is not included in the cooling device of the present invention.

The reverse osmosis membrane device (RO device) is for producing treated water having an electrical conductivity of less than 20 μS / cm.
As the RO device, for example, device types VCR40 series, VCR80 series, NER40 series, NER80 series, SHR series, E-mizu series and the like sold by Daisen Membrane Systems Co., Ltd. can be used.
The treated water of the RO device has an electric conductivity of 4 to 10 μS / cm, and is preferably substantially free of Ca ions, Mg ions, Na ions, Cl ions, ionic silica, and the like.

Although the number of the watering nozzles 12 may be one, it is preferable to have a plurality of watering nozzles 12, for example, 2 to 20 nozzles can be arranged on the surface side including the outside air intake 5 of one outdoor unit 1.
The hole diameter of the watering nozzle 12 (the inner diameter of the hole for watering) is preferably adjusted to a size capable of spraying droplets of 100 μm or less, and the size of the droplets is more preferably 50 to 100 μm, more preferably 50 to 70 μm is more preferable.
When the size of the droplet is within the above range, it becomes easy to supply the heat exchanger 3 together with the air flow, and the cooling efficiency can be improved.
For example, mist nozzles 125N, 10N, 14, 16N, 20N, 25, 32, 38, 100 manufactured by Ikeuchi Co., Ltd. can be used as those capable of spraying droplets in the above range.
The treated water of the RO apparatus has an electric conductivity of less than 20 μS / cm, preferably 4 to 10 μS / cm, and Ca ions, Mg ions, Na ions, Cl ions, ionic silica, etc. are substantially removed. Therefore, the spray nozzle can be prevented from being blocked, and the droplet size is stabilized.

The wind buffer means 20 is a member provided with a wind shielding surface (planar shielding portion) 21 having an opening 25. In FIG. 1 and FIG. 2, it has the leg part 26 for making it become more independent.
The wind buffer means 20 is arranged such that the flat shield 21 is spaced from the surface including the outside air intake 5, and the water spray means 10 is located between the flat shield 21 and the outside air intake 5. Is arranged.
The wind buffer means 20 acts so as to block the wind blown by the flat shielding portion 21 toward the outdoor unit 1 (the outside air intake 5), and the opening 25 flows toward the outside air intake 5 of the outdoor unit 1. It acts to form an air flow.
The flat shielding part 21 of the wind buffer means 20 is made of plastic, metal, wood, or a combination thereof, or a support member made of the above-described material (for example, a frame-shaped combination of beams, bars, pipes). The plastic sheet is supported by the above.

The opening 25 is a hole penetrating from the outer side surface 21a to the inner side surface 21b (the surface on the outdoor unit 1 side) of the flat shielding unit 21, and is formed in a horizontally long direction (from the first side 20a to the second side 20b). ing.
The opening diameter (z1) on the outer surface 21a side of the opening 25 and the opening diameter (z2) of the inner surface 21b are preferably the same (z1 = z2), but z1> z2 may be satisfied, or z1 <z2 may be satisfied. .
The opening part 25 has a total area (opening ratio) of the opening part within a range of 5 to 60% with respect to the area of the flat shielding part 21 (an area including the opening part 25).
The aperture ratio can be adjusted according to the surrounding environment where the outdoor unit 1 is disposed. For example, when the outdoor unit 1 is installed in a place where the wind easily passes or where the wind is strong, the aperture ratio is reduced, and the outdoor unit 1 has buildings, fences, etc. When it is installed in a place where it is difficult to pass, the aperture ratio can be increased.
The formation position, shape, size, number, and the like of the opening 25 can be adjusted within the range of the opening ratio.
The outdoor unit 1 and the wind buffering means 20 can be covered with a net or the like for preventing plant seeds, dust, insects and the like from entering, according to the surrounding environment.

The cooling device for the heat exchanger of FIGS. 1 and 2 combines one outdoor unit 1 and one wind cushioning means 20, but when using a plurality of outdoor units 1, two or more winds are used. The buffer means 20 can be combined.
In addition, when a plurality of outdoor units 1 are used, the plurality of outdoor units 1 and one wind buffer unit 20 can be combined by increasing the length of the wind buffer unit 20.

(2) Cooling device for heat exchanger in FIG. 3 FIG. 3 is a cooling device for a heat exchanger according to an embodiment different from those in FIGS. 1 and 2, except that the air cushioning means is different. It is the same as the cooling device for heat exchanger No. 2.
The wind buffer 120 includes a flat shielding part 121 having an opening 125a, a first side shielding part 122 having an opening 125b bent in the same direction from both sides of the flat shielding part 121, and an opening 125c. The second side shield part 123 is formed.
The wind cushioning means 120 is arranged with a space between the plane shielding portion 121 and the surface including the outside air intake 5, and the first side surface shielding portion 122 is spaced from the first side surface 2 a of the housing 2. The second side shield part 123 is disposed with a space from the first side surface 2 b of the housing 2.
The outside air intake 5 is in a state surrounded by the flat shielding part 121, the first side shielding part 122, and the second side shielding part 123.

The wind buffer means 120 acts so that the flat shield 121, the first side shield 122, and the second side shield 123 block the wind blown toward the outdoor unit 1 (the outside air intake 5), and the opening. 125a, 125b, and 125c act so as to form an air flow that flows toward the outside air intake 5 of the outdoor unit 1.
Note that the wind cushioning means 120 shown in FIG. 3 may be configured such that either one of the first side shield part 122 and the second side shield part 123 is not provided.
The plane shielding part 121, the first side shielding part 122, and the second side shielding part 123 of the wind cushioning means 120 are made of plastic, metal, wood or a combination thereof, and a support member made of the above-described material (for example, It is made up of a plastic sheet supported by a frame shape that combines beams, rods, and pipes).
The outdoor unit 1 and the wind buffering means 120 can be covered with a net or the like for preventing plant seeds, dust, insects and the like from entering, according to the surrounding environment.

The opening 125a is a hole penetrating in the thickness direction of the flat shielding part 121, and the total area (opening ratio) of the opening with respect to the area of the flat shielding part 121 (area including the opening 125a) is 5 to 60%. It will be in the range.
The opening 125b is a hole penetrating in the thickness direction of the first side shield 122, and the total area (opening ratio) of the opening with respect to the area of the first side shield 122 (area including the opening 125b) is It is in the range of 5 to 60%.
The opening 125c is a hole penetrating in the thickness direction of the second side shield part 123, and the total area (opening ratio) of the opening with respect to the area of the second side shield part 123 (area including the opening 125c) is It is in the range of 5 to 60%.
The opening ratios of the openings 125a, 125b, and 125c may be the same within the above range, or may be different for each opening.
The opening ratios of the openings 125a, 125b, and 125c can be adjusted according to the surrounding environment in which the outdoor unit 1 is disposed.
For example, when the outdoor unit 1 is installed in a place where the wind easily passes or where the wind is strong, the aperture ratio is reduced, and the outdoor unit 1 has buildings, fences, etc. When it is installed in a place where it is difficult to pass, the aperture ratio can be increased.
Further, for example, if the wind is likely to blow from the first surface 2a side to the second surface 2b side of the outdoor unit 1, the opening ratio of the opening 125b of the first side shield 122 is reduced, and the flat shield The opening ratio of the opening 125a of 121 and the opening ratio of the opening 125c of the second side shield part 123 can be increased.
The formation position, shape, size, number, and the like of the openings 125a, 125b, and 125c can be adjusted within the range of the aperture ratio.

In the heat exchanger cooling device of FIG. 3, one outdoor unit 1 and one wind buffer 120 are combined. However, when a plurality of outdoor units 1 are used, the length of the wind buffer 120 is long. By making the length longer, it is possible to combine a plurality of the outdoor units 1 and one wind cushioning means 120.
When a large number (for example, 10 or more) of the outdoor units 1 are arranged in one direction, the wind buffer 120 shown in FIG. 3 that does not have the first side shield 122 is arranged on one end side. The wind buffer 120 shown in FIG. 3 that does not have the second side shield 123 is arranged on the other end side, and the wind buffer 20 shown in FIG. Can be used as one wind buffer.

(3) Embodiment of FIG. 4 FIGS. 4A to 4H show the arrangement of different embodiments of the outdoor unit and the wind cushioning means. For example, different embodiments as shown in FIGS. 4A to 4H can be selected according to the wind direction of the surrounding environment where the outdoor unit 1 is installed.
In addition, all the white arrows have shown an example of the wind direction of ambient environment when the outdoor unit 1 is in an operation state.

FIG. 4A is an embodiment in which the wind buffering means 20 is arranged in the same manner as in the cooling devices of FIGS. 1 and 2, but the arrangement of the watering means 10 is different.
The wind buffer means 20 can also be disposed obliquely with respect to the outdoor unit 1 as shown in FIGS. 4 (b) and 4 (c).

FIG. 4D shows an embodiment in which the wind cushioning means 120 is arranged as in the cooling device of FIG.
FIG. 4E is a modification of FIG. 4D, and in the wind cushioning means 120, the first side shielding part 122 and the second side shielding part 123 spread outward with respect to the flat shielding part 121. It is formed as follows.
Here, for example, the first side shielding part 122 is in the form shown in FIG. 4E, and the second side shielding part 123 is in the same form as in FIG. 4D, or the first side shielding part 122 and the second side shielding part 122 are in the second form. The side shielding part 123 may have a configuration opposite to that described above.

FIG. 4 (f) is an embodiment using the wind cushioning means 120A in which the second side shield part 123 is removed from the wind cushioning means 120 shown in FIGS. 3 and 4 (d).
The wind cushioning means 120A has a flat shielding part 121A and a first side shielding part 122A, the planar shielding part 121A is arranged at a distance from the outside air intake 5, and the first side shielding part 122A is an outdoor unit. The first surface 2a is spaced from the first surface 2a.
The first side shield part 122A may be configured to expand outward as in FIG.

FIG. 4 (g) is similar to FIG. 4 (f), and shows the wind cushioning means 120B in which the first side shield 122 is removed from the wind cushioning means 120 shown in FIGS. 3 and 4 (d). This is the embodiment in use.
The wind cushioning means 120B has a flat shielding part 121B and a second side shielding part 123B, the planar shielding part 121B is arranged at a distance from the outside air intake 5, and the second side shielding part 123B is an outdoor unit. The first second surface 2b is spaced from the second surface 2b.
The second side shield part 123B may be configured to expand outward as in FIG. 4 (e).

FIG. 4 (h) is such that the flat shielding part 121 is removed from the wind cushioning means 120 shown in FIGS. 3 and 4 (d), and the first side shielding part 122C and the second side shielding part 123C. It is embodiment which has.
The first side shield part 122C is disposed at a distance from the first surface 2a of the outdoor unit 1, and the second side shield part 123C is disposed at a distance from the second surface 2b of the outdoor unit 1.
The first side shield part 122C may be disposed so as to be inclined with respect to the first surface 2a of the outdoor unit 1, and the second side shield part 123C is opposed to the second surface 2b of the outdoor unit 1. And may be arranged so as to be inclined.

(4) Embodiment of FIG. 5 FIGS. 5A and 5B are views showing the positional relationship between the shielding surface (planar shielding portion) 21 and the opening 25 of the wind cushioning means 20.
The opening 25 is a hole that penetrates from the outer side surface 21 a of the flat shielding unit 21 to the inner side surface 21 b (surface that becomes the outdoor unit 1 side).
In FIGS. 5A and 5B, the opening 25 is a horizontally long rectangle, but it may be a vertically long rectangle, a circle, an ellipse, a triangle, a pentagon, a hexagon or more polygon, and an indefinite shape.
5 (a) and 5 (b), the openings 25 are arranged at equal intervals, but may be arranged partially biased.
For example, when the wind cushioning means 20 is used in the state of being arranged as shown in FIG. 4B, the opening is provided only on the left half side (half on the second side 20b side) in FIG. 25 can be used, and the second side 20b can be disposed close to the outdoor unit 1.
Further, for example, when the wind cushioning means 20 is used in the state of being arranged as shown in FIG. 4C, it is opened only on the right half side (half on the first side 20a side) in FIG. 5A. Using what formed the part 25, it can also arrange | position so that the 1st edge | side 20a may become a position near the outdoor unit 1. FIG.

(5) Embodiment of FIG. 6 The opening part 25 of the wind buffer means 20 should just be the hole penetrated in the thickness direction, for example, is carried out like embodiment shown to Fig.6 (a)-(d). be able to.
FIG. 6A shows an embodiment in which the opening 25 is formed in a direction orthogonal to the height direction (long axis direction).
FIG. 6B shows an embodiment in which the opening 25 is formed to be inclined downward from the outer surface 21a to the inner surface 21b.
FIG. 6C shows an embodiment in which the opening 25 is formed to be inclined upward from the outer surface 21a to the inner surface 21b.
FIG. 6D shows an embodiment in which the opening 25 is formed by mixing the openings 25 in FIGS. 6A, 6 </ b> B, and 6 </ b> C.

(6) Embodiment of FIG. 7 The opening part 25 of the wind buffer means 20 should just be the hole penetrated in the thickness direction, for example, is made into embodiment as shown to FIG.7 (a)-(d). be able to.
FIG. 7A shows an embodiment in which the opening 25 is formed in a direction orthogonal to the height direction (long axis direction).
On the inner surface 21b side of the opening 25, a cylindrical air flow control means 27 is formed so as to protrude from the inner surface 21b.

FIG. 7B shows an embodiment in which the opening 25 is formed to be inclined downward from the outer surface 21a to the inner surface 21b.
On the inner surface 21b side of the opening 25, a cylindrical air flow control means 27 is formed so as to protrude from the inner surface 21b.

FIG. 7C shows an embodiment in which the opening 25 is formed to be inclined upward from the outer surface 21a to the inner surface 21b.
On the inner surface 21b side of the opening 25, a cylindrical air flow control means 27 is formed so as to protrude from the inner surface 21b.

FIG. 7D shows an embodiment in which the opening 25 is formed by mixing the openings 25 in FIGS. 7A, 7B, and 7C.
On the inner surface 21b side of the opening 25, a cylindrical air flow control means 27 is formed so as to protrude from the inner surface 21b.
The cylindrical airflow control means 27 shown in FIGS. 7A to 7D functions to control the airflow through the opening 25 in a specific direction.

(7) Embodiment of FIGS. 8 and 9 The wind cushioning means 220 shown in FIG. 8 includes a leg portion 226 and a top plate portion 227, and a first side plate portion 228 and a second plate 227 between the leg portion 226 and the top plate portion 227. The side plate portions 229 are combined so as to form a frame.
A first buffer plate 221, a second buffer plate 222, and a third buffer plate 223 are spanned between the first side plate portion 228 and the second side plate portion 229 in order from the top plate portion 227 side.
Both end sides in the length direction of the first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 are fixed to the first side plate portion 228 and the second side plate portion 229, respectively.
In FIG. 8, three sheets of the first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 are used. However, the number of buffer plates is not limited, and four or more buffer plates are used. It can also be used in combination.

The first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 can change the angle α with respect to the direction of the axis X as shown in FIGS.
In FIG. 9A, the angle α is an obtuse angle, in FIG. 9B, the angle α is 90 degrees, and in FIG. 9C, the angle α is an acute angle.
In FIGS. 9A to 9C, the first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 have the same angle α, but the angles α are different. You can also.
For example, the angle α can be changed by adjusting the attachment positions of the first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 with respect to the first side plate portion 228 and the second side plate portion 229.
The method for changing the mounting position as described above is not particularly limited. For example, a plurality of through holes having different heights are opened at the attachment positions of the first buffer plate 221 of the first side plate portion 228 and the second side plate portion 229, and two holes are formed on both end surfaces in the length direction of the first buffer plate 221. A method of fixing with a bolt or the like while adjusting the position of each hole in advance can be applied. The same applies to the second buffer plate 222 and the third buffer plate 223.

A first opening 225a is formed between the top plate 227 and the first buffer plate 221, and a second opening 225b is formed between the first buffer plate 221 and the second buffer plate 222, and the second buffer A third opening 225 c is formed between the plate 222 and the third buffer plate 223, and a fourth opening 225 d is formed between the third buffer plate 223 and the leg 226.
The first opening 225a, the second opening 225b, the third opening 225c, and the fourth opening 225d are openings formed by elongated gaps extending in the length direction. By changing the angle α described above, the openings The width (w1 shown in FIGS. 9A to 9C) can also be changed.
The opening areas of the first opening 225a, the second opening 225b, the third opening 225c, and the fourth opening 225d are obtained from “width w1 × length” of each opening.
However, the width w1 affects the buffering action against the air flow (indicated by white arrows in FIGS. 9A to 9C). In FIGS. The width w1 of the first opening 225a and the fourth opening 225d is the narrower width.

The wind buffer means 220 shown in FIG. 8 has a similar form to that shown in FIG. 2, but can be formed in the same form as the wind buffer means 120 shown in FIG.
When the configuration similar to that of the wind buffer means 120 shown in FIG. 3 is used, the first buffer plate 221 and the second buffer plate are respectively provided on the flat shield 121, the first side shield 122, and the second side shield 123. 222 and a third buffer plate 223 can be attached.
The first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 may be curved or have a protrusion on the plane, in addition to a flat plate whose side shape is illustrated.
Further, the first buffer plate 221, the second buffer plate 222, and the third buffer plate 223 may have a side shape such as a triangle, trapezoid, or crank shape.

<Cooling method of heat exchanger>
A cooling method using the heat exchanger cooling device of the present invention will be described with reference to FIGS.
When the operation of the indoor unit of the cooling device is started, the operation of the outdoor unit 1 is also started. The operation of the outdoor unit 1 is started, the fan 4 is operated, the air taken in from the outside air intake 5 is blown to the heat exchanger 3, and the heat exchanger 3 is cooled.
In parallel with the operation of the outdoor unit 1, the operation of the RO device is also started to produce treated water having an electric conductivity of less than 20 μS / cm, preferably in the range of 4 to 10 μS / cm.
The treated water having an electrical conductivity of less than 20 μS / cm is supplied from the water supply pipe 11 and sprayed from the water spray nozzle 12 to the outdoor air intake 5 of the outdoor unit 1.
At this time, as described above, when spraying into droplets having a size of 100 μm or less, water hardly drops on the surface where the outdoor unit 1 is installed (for example, a concrete surface), and the installation surface Since generation | occurrence | production of moss etc. can be suppressed, it is preferable.
The treated water sprayed on the outside air intake 5 is sent to the heat exchanger 3 together with the air blown by the fan 4 and adheres to the surface of the heat exchanger 3.
Since the treated water adhering to the surface of the heat exchanger 3 evaporates and takes heat at that time, the cooling effect of the refrigerant by the heat exchanger 3 is enhanced.
In addition, since treated water has low electrical conductivity (that is, it does not substantially contain scale components), even if water spraying is continued for a long period of time, it can be scaled to the outside air intake 5, the fan 4, the heat exchanger 3, etc. Ingredients do not adhere.

When the heat exchanger is cooled in this manner, depending on the situation of the location where the outdoor unit 1 is installed, the water sprayed on the outside air intake 5 is scattered by the influence of the wind, and most of the heat exchanger 3 It may be the case that it does not reach the situation. Such a situation occurs remarkably when the droplets of water sprayed from the watering nozzle 12 are small.
However, in the cooling device of the embodiment shown in FIG. 1 and FIG. 2, since the water spray nozzle 12 is disposed between the outdoor unit 1 and the wind buffer means 20, when spraying treated water from the water spray nozzle 12, It becomes difficult to be affected by the wind blowing toward the machine 1.
When the wind blows from the front to the outdoor unit 1, the wind passes through the opening 25, but the flat shielding unit 21 blocks the wind, so that the amount of air reaching the outdoor unit 1 (watering nozzle 12) is controlled. (I.e., the wind strength is reduced).
Further, since the fan 4 is operating, the wind passing through the opening 25 generates an air flow from the opening 25 to the outside air intake 5.
For this reason, almost all of the treated water sprayed from the water spray nozzle 12 is sent to the heat exchanger 3 together with the air flow and used for cooling the heat exchanger 3 (that is, not used for cooling). The amount of treated water that splatters is reduced, and cooling efficiency is increased.

Furthermore, according to the wind condition of the place where the outdoor unit 1 is installed, the wind cushioning means 120 as shown in FIG. 3 can be used, and the embodiment shown in FIGS. In this manner, the positional relationship between the outdoor unit 1 and the wind buffer means 20 and the wind buffer means 120 can also be adjusted.
Further, when the wind cushioning means 220 as shown in FIG. 8 is used, the wind buffering means 220 is in any one of the forms shown in FIGS. 9A to 9C according to the wind condition at the place where the outdoor unit 1 is installed. In addition, the angle α of the first buffer plate 221, the second buffer plate 222, and the third buffer 223 can be appropriately adjusted.

Example 1
Using the heat exchanger cooling device, the cooling operation was performed under the following conditions.
<Cooling device for outdoor unit and heat exchanger>
Outdoor unit: Three COOLSCAPE THVD-100 units were used. Each outdoor unit has a heat transfer surface (a surface having an outside air intake) on both the front surface and the back surface, and thus has a total of six heat transfer surfaces.
RO treatment apparatus: One E-mizu200 (treatment amount: 200 L / hr, electrical conductivity of treated water: 7 to 10 μS / cm) manufactured by Daisen Membrane Systems Co., Ltd. was used.
Spray nozzles: 8 mist nozzles 125N made by Ikeuchi Co., Ltd. were attached to each of the heat transfer surfaces at intervals of 300 mm on the upper side.
Wind cushioning means: A black plastic sheet having a thickness of 10 mm supported by a metal frame and having a total of two holes as shown in FIG. 5 (a) was used. The opening area was 9%. The wind buffer means was in contact with the upper part of the outdoor unit, and was arranged in front of the heat transfer surface at an interval of about 70 cm at the lower part of the outdoor unit.

<Cooling operation conditions>
Location: A commercial facility in Bangkok, Thailand Period: 5 days from April 7th to April 11th, 2014 Spray time: 2: 30-5: 00 at night, 13: 30-15: 00 during the day
Spray amount: 0.06 L / min per nozzle, 173 L / Hr as a whole, droplet diameter of about 60 μm
The passage to the place where the outdoor unit was installed was closed (however, the passage of the wind was not obstructed) so that the observation was not possible from the outside.

During the above period, the vehicle was always operated while plotting the power consumption for cooling.
In the operation on April 10, the power consumption that was at least 49 kW during the daytime when spraying was stopped decreased to 37 kW during spraying, and a 24-25% reduction in power consumption was observed. It was.
At night, during the time when spraying was stopped, the power consumption of at least 42 kW decreased to 36 kW during spraying, and a 14-15% reduction in power consumption was observed.

Example 2
Using the heat exchanger cooling device, the cooling operation was performed under the following conditions.
<Cooling device for outdoor unit and heat exchanger>
Outdoor unit: A Daikin RUR20NYIS Thai model was used. One with a heat transfer surface (outside air intake) only on one side.
RO treatment apparatus: One E-mizu200 (treatment amount: 200 L / hr, electrical conductivity of treated water: 7 to 10 μS / cm) manufactured by Daisen Membrane Systems Co., Ltd. was used.
Spray nozzles: A total of 38 mist nozzles 125N manufactured by Ikeuchi Co., Ltd., each including 19 nozzles in the middle and lower portions of the heat transfer surface of the outdoor unit.
Wind cushioning means: A 10 mm-thick plastic black sheet supported by a metal frame and having a total of 10 holes as shown in FIG. 5 (a) was used. The opening area was 25%. The wind buffer means was arranged in front of the heat transfer surface with an interval of about 30 cm.

<Cooling operation conditions>
Location: Factory B in Lopburi, Thailand Period: November 20, 2014 Spray volume: 200L / Hr in total, droplet diameter 60μm

Between 10:30 and 11:30, the outdoor unit was operated without spraying water treated by the RO treatment apparatus and without using a wind buffer. Power consumption remained at 8.3 kW.
At 11:30, no wind buffering means was used, and spraying of treated water by the RO treatment apparatus was started and continued for 10 minutes. The power consumption has dropped to 7.1 kW. When spraying of the treated water by the RO treatment apparatus was stopped, the power consumption returned to 8.3 kW.
In the case where the wind buffer means was not used, a power consumption reduction effect of 15% was confirmed.
When spraying of the treated water by the RO treatment apparatus was started again at 12:40, the power consumption once dropped to 6.1 kW, but gradually increased to 7 kW as the temperature rose.
At 13:30, spraying of treated water by the RO treatment apparatus was stopped, and a wind buffering means was installed at a predetermined position.
The power consumption until the installation of the wind buffering means was 8.5 to 8.6 kW, but it was 8.3 kW after the installation.
At 14:00, when spraying of treated water by the RO treatment equipment was resumed with the wind buffer installed, the power consumption dropped sharply, and after 30 minutes of resumption, the power consumption remained around 6.5 kW. . The reduction effect of 22% power consumption was confirmed.
During the operation time, the passage to the place where the outdoor unit was installed was closed (but not to block the passage of the wind) so that it could not be observed from the outside.

Example 3
Using the heat exchanger cooling device, the cooling operation was performed under the following conditions.
<Cooling device for outdoor unit and heat exchanger>
Outdoor unit: 9 units made by YORK were used. One with a heat transfer surface (outside air intake) only on one side.
RO treatment apparatus: Two E-mizu200 (treatment amount: 200 L / hr, electrical conductivity of treated water: 7 to 10 μS / cm) manufactured by Daisen Membrane Systems Co., Ltd. were used.
Spray nozzle: 10 nozzles were arranged on each heat transfer surface of an outdoor unit.
Wind buffering means: An opening 25 is formed on a 10 mm thick tin plate as shown in FIG. 6C so as to incline upward from the outer surface 21a to the inner surface 21b, and a total of 14 holes are formed. I used something. The opening area was 30%. The wind buffer means was arranged in front of the heat transfer surface with an interval of about 30 cm.

<Cooling operation conditions>
Location: Factory C in Thailand Period: 10 days from August 23rd to September 1st, 2014 Spray amount: 0.3L / min per nozzle, 1440L / Hr overall
Spraying time: 9: 00-10: 00
11: 00〜12: 00
13: 00-14: 00
15: 00-16: 00
17: 00-19: 00

During the above spraying time, the treated water by the RO treatment apparatus was always sprayed, and during other time zones, spraying was stopped and the power consumption was measured.
For 10 days, the power consumption during the spraying time is lower than the power consumption during the time when spraying was stopped during the day, ranging from 11% (9.4 kW → 8.4 kW) to 15% (14.8 kW → 12.5 kW). The reduction effect of power consumption was recognized.
During the operation time, the passage to the place where the outdoor unit was installed was closed (but not to block the passage of the wind) so that it could not be observed from the outside.

  The cooling device and cooling method for a heat exchanger according to the present invention reduce power consumption in all of the facilities equipped with cooling facilities such as various factories, various commercial facilities, airports, stations, schools, companies, apartment houses, and private houses. It can be used as a cooling device and a cooling method.

DESCRIPTION OF SYMBOLS 1 Outdoor unit 2 Housing 3 Heat exchanger 4 Fan 5 Outside air intake 10 Water sprinkling means 11 Water supply pipe 12 Water sprinkling nozzle 20 Wind buffer means 21 Shielding surface (plane shielding part)
25 opening

Claims (7)

A heat exchanger, a cooling device for the heat exchanger in an outdoor unit including a fan, a condenser, and a compressor for taking outside air from an outside air intake port, blowing the air to the heat exchanger, and cooling the air, Means and wind buffer means,
The watering means is
It has a reverse osmosis membrane device for obtaining treated water having an electrical conductivity of less than 20 μS / cm, a water pipe for feeding the treated water, and a watering nozzle for sprinkling the treated water. The watering nozzle is arranged on the surface side including the outside air intake port,
The wind buffer means is
It is a member having a wind shielding surface having an opening, and the total area of the opening with respect to the area of the shielding surface (area including the opening) is in the range of 5 to 60%,
The shielding surface having the opening is arranged at a distance from the surface including the outside air intake port,
When the fan of the outdoor unit is activated, outside air passes through the opening of the wind buffer means, is taken in from the outside air intake, and is blown to the heat exchanger,
The position of the opening of the wind buffer means and the position of the watering nozzle are adjusted so that the watering nozzle is positioned in the air flow from the opening to the outside air intake. Cooling system. The wind buffer means is
The shielding surface comprises a planar shielding part having an opening,
The cooling device for a heat exchanger according to claim 1, wherein the flat shielding portion is disposed at a position facing a surface including the outside air intake and the watering nozzle. The wind buffer means is
The shielding surface includes a planar shielding part having an opening, a first side shielding part having an opening and a second side shielding part having an opening bent in the same direction from both sides of the planar shielding part. And
The plane shielding portion is spaced at a position facing the surface including the outside air intake and the watering nozzle,
The first side surface shielding portion and the second side surface shielding portion are on the surface side including the outside air intake port, and are disposed at a distance from the surface including the outside air intake port and the watering nozzle,
The said wind buffer means is arrange | positioned so that the surface containing the said external air intake may be enclosed by the said plane shielding part, the said 1st side surface shielding part, and the said 2nd side surface shielding part. Heat exchanger cooling system.   The cooling device for a heat exchanger according to claim 1, wherein the wind buffer means is made of a flat plate having an opening or a sheet having an opening on the shielding surface.   The wind buffer means includes an opening formed in the shielding surface and a control means attached to the opening for controlling the air flow through the opening in a specific direction. The heat exchanger cooling device according to claim 1.   The cooling device for a heat exchanger according to claim 1, wherein the watering nozzle is capable of spraying droplets of 100 μm or less. A heat exchanger cooling method using the heat exchanger cooling device according to any one of claims 1 to 6,
When the operation of the outdoor unit is started, the fan is activated, and the air taken in from the outside air intake is blown to the heat exchanger,
Spraying treated water having an electric conductivity of less than 20 μS / cm from the watering nozzle of the watering means to the outside air intake of the outdoor unit,
A cooling method for a heat exchanger, wherein the sprayed treated water is sent to the heat exchanger and cooled together with the air flow from the outdoor air intake port of the outdoor unit to the heat exchanger through the opening of the wind buffer means. .

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