JP2019020040A - Cooling device - Google Patents

Abstract

To provide a cooling device which increases a temperature drop range of an environment formed by an airflow space which encloses mist sprayed from a mist nozzle even during daytime when an outdoor temperature is high.SOLUTION: A cooling device includes: a supply port 20 into which air flows; a supply duct 22 in which the air flowing from the supply port 20 flows upward; a blower 30 which is provided above the supply port 20 in the supply duct 22 and generates airflow flowing in the supply duct 22; an outlet duct 23 provided with an air outlet from which airflow that passes through the blower 30 blows downward; and a spray nozzle 26 which is provided at the outlet duct 23 and sprays mist to the lower side away from the outlet duct 23 toward a space, in which natural wind is blocked, by the airflow blowing downward from the outlet port 24. A supply port 20 for taking air cooled by the mist toward the airflow blown downward from the air outlet is disposed at the supply duct 22.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling device that cools an outdoor space by spraying mist.

  When the summer temperature is high, the temperature near the road surface may become very high due to reflection from the road surface. In this case, the temperature of the passer's sensation increases and the discomfort of the passerby increases.

To mitigate such discomfort, Patent Document 1, and the body, and at least one mist nozzle installed in the periphery of the main body outward spraying water mist, above the mist nozzle The technology regarding the cooling device provided with the ventilation hole which is installed in 1 and which blows off airflow toward the mist sprayed from the mist nozzle is disclosed. In such a cooling device, the environment formed by the airflow space that encloses the mist sprayed from the mist nozzle can be efficiently cooled using the cooling action by the heat of vaporization of the mist.

Japanese Patent Laid-Open No. 2006-028217

  However, in the prior art described in Patent Document 1, the temperature of the airflow that blows out from the vent hole rises on a day when the outside air temperature is high. The amount of decrease is small.

  The present invention solves the above-mentioned conventional problems, and increases the amount of temperature decrease in the environment formed by the airflow space that wraps the mist sprayed from the mist nozzle even during the daytime when the outside air temperature is high. It is an object of the present invention to provide a cooling device that can perform the above.

  In order to solve the conventional problems, the cooling device of the present invention includes a supply port through which air flows, a supply duct through which air flows from the supply port flows upward, and the supply port. A blower that generates a flow of air that flows through the supply duct, a blowout duct that is provided with a blowout outlet that passes through the blower and blows downward, and is provided in the blowout duct. A spray nozzle that sprays mist downwardly away from the blowout duct toward a space that blocks natural wind by an airflow blown downward from the blowout opening, and the airflow blown downward from the blowout opening On the other hand, the supply port for taking in air cooled by fog is arranged in the supply duct.

  As a result, the air in the space blocked from the natural wind is circulated by the air curtain generated by the air flow blown out from the outlet, and is repeatedly cooled by the heat of vaporization of the mist, so the temperature of the air in the space The amount of decrease can be increased.

  The cooling device of the present invention can increase the temperature drop amount of the environment formed by the airflow space that wraps the mist sprayed from the mist nozzle even during the daytime when the outside air temperature is high.

Side view showing the configuration of the cooling device 10A according to the first embodiment. Front view showing a configuration of a cooling device 10A according to the first embodiment. The front view which shows the structure of the cooling device 10B which concerns on Embodiment 2. FIG. Side view showing a configuration of a cooling device 10C according to the third embodiment.

  In the first aspect of the present invention, the cooling device is provided above the supply port in the supply port through which air flows in, the supply duct through which the air flowing in from the supply port flows upward, A blower that generates a flow of air that flows through the duct, a blowout duct that is provided with a blowout outlet that passes through the blower and blows downward, and is provided in the blowout duct. A spray nozzle that jets mist downward from the blowout duct toward the space that shuts off the airflow, and a supply port that takes in the air cooled by the mist toward the airflow blown downward from the blowout port, It is located in the supply duct.

  According to the said structure, the air in the space interrupted | blocked from the natural wind by the air curtain which the airflow which blown off from said blower outlet produces | generates circulates, and is cooled repeatedly by the heat of vaporization of fog. Therefore, the temperature drop amount of the air in the space can be increased.

  The second invention is that, in the first invention, the area of the supply port is larger than the area of the outlet.

  According to this configuration, when the air flows through the air passage between the supply port and the outlet, the area of the supply port is larger than the area of the outlet, so that the pressure loss at which the air passes through the supply port is relatively low. Since the air flow rate of the blower 30 at the same rotation speed increases, the air flow rate increases, and the heat exchange amount between the relatively low temperature air flowing in from the supply port and the members constituting the air path increases. The temperature of the member which comprises an air path falls. Thereby, since the amount of heat transfer per unit flow rate can be reduced, air having a low temperature can be blown out from the outlet. Therefore, even if the solar radiation is strong and the main body becomes hot, the amount of temperature drop of the air in the space can be increased.

  A third invention is that, in the first or second invention, at least two blowers are arranged in parallel to the airflow.

  According to the said structure, even if it is a case where solar radiation is strong and a main body becomes high temperature, a relatively low temperature air which flowed in from the supply port and an air path are comprised by parallelization of an air blower and air flow volume increasing. The temperature of the member which comprises an air path falls because the amount of heat exchanges with a member increases. Thereby, since the amount of heat transfer per unit flow rate can be reduced, air having a low temperature can be blown out from the outlet.

  Therefore, even if the solar radiation is strong and the main body becomes hot, the amount of temperature drop of the air in the space can be increased.

  A fourth invention is that, in the first or second invention, at least two blowers are arranged in series with respect to the flow of airflow.

According to this configuration, even if the natural wind is strong and the solar radiation is strong and the main body becomes hot, the air curtain force is strengthened by increasing the static pressure in the machine by serializing the blower. As a result of the increase, the amount of heat exchange between the relatively low temperature air flowing in from the supply port and the member constituting the air passage increases, so that the temperature of the member constituting the air passage decreases. Thereby, since the amount of heat transfer per unit flow rate can be reduced, air having a low temperature can be blown out from the outlet.

  Therefore, even if the natural wind is strong, the solar radiation is strong, and the main body is at a high temperature, the temperature drop amount of the air in the space can be increased.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the present embodiment.
(Embodiment 1)
[Configuration of Cooling Device 10A]
1 and 2 are diagrams showing a configuration of a cooling device 10A according to the first embodiment. FIG. 1 is a side view of the side surface of the cooling device 10A. FIG. 2 is a front view of the cooling device 10A.

  In FIG. 1 and FIG. 2, the cooling device 10 </ b> A includes a supply port 20, a supply duct 22, a blower 30, a blowout duct 23, a blowout port 24, and a spray nozzle 26.

  External air flows from the supply port 20. The opening direction of the supply port 20 can be set freely. For example, as shown in FIG. 1, by opening the supply port 20 in the horizontal direction, rainwater can be prevented from entering from the supply port 20 during rainy weather.

  In the supply duct 22, the air flowing in from the supply port 20 flows upward.

  The air outlet 24 is provided at a position above the supply port 20 in the air outlet duct 23 and blows out the air flowing through the air outlet duct 23 downward. A plurality of air outlets 24 are provided. However, only one outlet 24 may be provided. The cross-sectional shape of the air outlet 24 is rectangular, but it may be circular, elliptical, or polygonal.

  The blower 30 generates the above-described air flow. That is, the blower 30 flows in from the supply port 20, passes through the supply duct 22, is pressurized by the blower 30, and generates an airflow that blows out from the blowout port 24 through the blowout duct 23.

  The spray nozzle 26 is provided on the lower surface of the blowing duct 23 and jets mist downwardly away from the blowing duct 23. A plurality of spray nozzles 26 are provided. However, only one spray nozzle 26 may be provided.

  When the supply port 20 takes in the air cooled by the mist in the space 50 partitioned by the air curtain formed by the boundary line 51 extending in the direction of the airflow blown out from each air outlet 24, the temperature of the intake air is reduced. It is arranged so as to be below a predetermined temperature relative to the temperature of the outside environment.

  Two or more supply ports 20 are arranged. However, only one supply port 20 may be provided.

  Further, the area of the supply port 20 is larger than the area of the air outlet 24.

Further, the blower 30 may be installed at any position as long as it is above the supply port 20 and on the air path reaching the outlet 24.
[Operation]
Hereinafter, the operation and action of the cooling device 10A according to the first embodiment will be described with reference to FIGS.

  When the blower 30 is in operation, an airflow that flows in from the supply port 20 and blows out from the outlet 24 through the supply duct 22 is generated. Here, not only cold air but also non-evaporated mist (water droplets) exist in the space 50 partitioned by the air curtain. Since the supply duct 22 is a vertical duct, water droplets having a relatively large particle size contained in the air flowing in from the supply port 20 fall by their own weight and are removed. Can prevent large water droplets from blowing out. On the other hand, water droplets having a relatively small particle diameter in the mist contained in the air flowing in from the supply port 20 evaporate in the process of passing through the supply duct 22, and the temperature of the air blown out from the outlet 24 can be lowered.

  The mist sprayed from the spray nozzle 26 is restrained from flowing out of the space 50 partitioned by the air curtain by the air flow blown out from the blower outlet 24, stays in the space 50 and evaporates. The air in the space 50 is cooled by the heat of vaporization of the fog.

  The supply port 20 is arrange | positioned in the position which takes in the air of 50 in the space partitioned off with the air curtain. Therefore, air cooled by the above-described vaporization heat of the mist flows from the supply port 20. The air is blown out from the outlet 24 again and is cooled by the heat of vaporization of the mist as described above. That is, the air in the space partitioned by the air curtain is repeatedly cooled by the heat of vaporization of the mist. Thereby, the temperature fall amount of the air in the said space 50 can be enlarged.

  Thus, by circulating the air in the space 50 partitioned by the air curtain, the temperature drop amount of the air in the space 50 can be increased with a relatively small spray amount (that is, the amount of water used). it can. This is because in order to increase the temperature drop of the air in the space 50 without circulating the air in the space partitioned by the air curtain, a large amount of mist is ejected in order to increase the heat of vaporization per unit volume. This is because it is necessary to use a large amount of water.

  Moreover, since the area of the supply port 20 is larger than the area of the blower outlet 24, the amount of heat exchange between the air flowing in from the supply port and the members constituting the air path increases due to the increase in the air flow rate accompanying the pressure loss reduction. As a result, the temperature of the members constituting the air path decreases. That is, the amount of heat that the air flowing through the air passage obtains from the outside air temperature through the air passage at a unit flow rate can be made relatively small. Therefore, even in an environment where the solar radiation is strong and the temperature of the main body is high, an increase in the temperature of the air while passing through the air passage is suppressed, so that the amount of decrease in the temperature of the air in the space 50 can be increased.

  The cooling device 10 </ b> A of the present embodiment is provided above the supply port 20 in the supply port 20 through which air flows, the supply duct 22 in which the air that flows in from the supply port 20 flows upward, and the supply duct 22. A blower 30 that generates a flow of air flowing through the supply duct 22, a blowout duct 23 that is provided with a blowout outlet that passes through the blower 30 and blows downward, and is provided in the blowout duct 23. A spray nozzle 26 that blows mist downward from the blowout duct 23 toward a space that blocks natural wind by an airflow blown downward from the blower 24, and toward an airflow blown downward from the blowout port The supply port 20 for taking in the air cooled by the mist is arranged in the supply duct 22.

For example, as shown in FIGS. 1 and 2, the opening of the supply port 20 is installed on the downstream side of the supply duct 22, so that the boundary line 51 extends in the direction of the air flow blown downward from the blowout port 24. The supply port 20 can be arranged at a position for taking in the air in the space 50 partitioned by the air curtain.
(Embodiment 2)
As described in the first embodiment, the air passage from the supply port 20 to the blowout port 24 is installed in a place with strong solar radiation and becomes hot, and the air sucked from the supply port 20 is supplied from the supply port 20. Heat received from the air path to the outlet 24 and the air blown from the outlet 24 can be warmed.

When the blower 30 is provided between the supply port 20 and the outlet 24, it is desirable to increase the air volume of the blower 30 in order to lower the temperature of the air blown from the outlet 24. Therefore, a configuration that prevents the temperature of the air blown from the outlet 24 from rising will be described in the second and third embodiments.
[Configuration of Cooling Device 10B]
FIG. 3 is a diagram illustrating a configuration of a cooling device 10B according to the second embodiment. FIG. 3 is a front view of the cooling device 10B. In addition, about the same component as FIG. 1, the same referential mark is used and detailed description is abbreviate | omitted.

  In FIG. 3, in the cooling device 10 </ b> B, two blowers 30 </ b> A are arranged in parallel with the airflow in the air path from the supply port 20 to the air outlet 24.

In FIG. 3, three or more blowers 30 </ b> A may be provided in parallel.
[Operation]
Hereinafter, the operation and action of the cooling device 10B according to Embodiment 2 will be described with reference to FIG.

  Air that flows in from the supply port 20 and reaches the blower 30A through the supply duct 22 is distributed, sucked into the two blowers 30A, boosted, and blown out.

Thereby, even if the solar radiation is strong and the main body becomes high temperature, the amount of heat exchange between the air flowing in from the supply port and the member constituting the air path is increased by increasing the air flow rate by parallelizing the blower. The temperature of the member which comprises an air path falls by increasing. Thereby, since the amount of heat transfer per unit flow rate can be reduced, air having a low temperature can be blown out from the outlet.
(Embodiment 3)
[Configuration of Cooling Device 10C]
FIG. 4 is a diagram showing a configuration of a cooling device 10C according to the third embodiment. FIG. 4 is a side view of the cooling device 10C. In addition, about the same component as FIG. 1, the same referential mark is used and detailed description is abbreviate | omitted.

  In FIG. 4, in the cooling device 10 </ b> C, two blowers 30 </ b> B are arranged in series with respect to the airflow in the air path from the supply port 20 to the air outlet 24.

In FIG. 4, three or more blowers 30B may be provided in series.
[Operation]
Hereinafter, the operation and action of the cooling device 10C according to Embodiment 3 will be described with reference to FIG.

  The air that flows in from the supply port 20, passes through the supply duct 22, and reaches the blower 30 </ b> B is sucked into the first blower 30 </ b> B, boosted, and blown out. Next, the air is sucked into the second blower 30B, further boosted and blown out.

  As a result, even when the natural wind is strong and the solar radiation is strong and the main body becomes hot, the air curtain force is strengthened and the air flow rate is increased by increasing the static pressure in the machine by serializing the blower. Thereby, the temperature of the member which comprises an air path falls because the amount of heat exchange with the air which flowed in from the supply port and the member which comprises an air path increases. Thereby, since the amount of heat transfer per unit flow rate can be reduced, air having a low temperature can be blown out from the outlet.

  Therefore, even if the natural wind is strong, the solar radiation is strong, and the main body has a high temperature, the temperature drop amount of air in the space can be increased.

  Each of the above-described embodiments is merely an example of the implementation of the present invention, and the technical scope of the present invention should not be construed as being limited thereto. That is, the present invention can be implemented in various forms without departing from the gist or the main features thereof.

  The present invention is suitable for use in a cooling device that cools the outdoor and semi-outdoor spaces by ejecting mist into the outdoor and semi-outdoor spaces.

10A, 10B, 10C Cooling device 20 Supply port 22 Supply duct 23 Outlet duct 24 Outlet 26 Spray nozzle 30, 30A, 30B Blower

Claims (4)

A supply port for air to flow in;
A supply duct through which air flowing in from the supply port flows upward;
In the supply duct, a blower that is provided above the supply port and generates a flow of air flowing through the supply duct;
A blowout duct provided with a blowout outlet that passes through the blower and blows downward;
A spray nozzle that is provided in the blowout duct and sprays mist downward from the blowout duct toward a space that blocks natural wind by an airflow blown downward from the blowout outlet;
The cooling apparatus according to claim 1, wherein the supply port for taking in air cooled by mist is arranged in the supply duct toward a space that blows downward from the outlet.   The cooling device according to claim 1, wherein an area of the supply port is larger than an area of the air outlet.   The cooling device according to claim 1 or 2, wherein at least two of the blowers are arranged in parallel to the flow of airflow. The cooling device according to claim 1 or 2, wherein at least two of the blowers are arranged in series with respect to a flow of airflow.