JP6887128B2 - Cooling system - Google Patents

Description

The present invention relates to a cooling device including a two-fluid mist nozzle.

Conventionally, in this type of cooling device, mist is generated by using a two-fluid mist nozzle that miniaturizes water by air, and the space is cooled by utilizing the heat of vaporization cooling of the mist.

As the two-fluid mist nozzle, an internal mixing type (for example, Patent Document 1) for refining water inside the nozzle and an external mixing type (for example, Patent Document 2) for refining water outside the nozzle are known. .. All of these are made into fine particles by crushing water by a jet of air.

FIG. 3 shows an outline of the internal mixing type two-fluid mist nozzle described in Patent Document 1. As shown in FIG. 3, the internal mixing type two-fluid mist nozzle has a water supply path 101 for supplying water, an air supply path 102 for supplying air, and a water and air supply path supplied from the water supply path 101. It includes a gas-liquid mixing unit 103 that mixes the air supplied from the 102, and a spray hole 104 that ejects water and air that have been refined by the gas-liquid mixing unit 103.

FIG. 4 shows an outline of the external mixing type two-fluid mist nozzle described in Patent Document 2. As shown in FIG. 4, the external mixing type two-fluid mist nozzle ejects water supplied from the water supply path 201 for supplying water, the air supply path 202 for supplying air, and the water supplied from the water supply path 201. It includes an ejection hole 203, an air ejection hole 204 for ejecting the air supplied from the air supply path 202, and a gas-liquid mixing section 205 provided outside the nozzle and crushing the ejected water with the ejected air.

In addition, the two-fluid mist nozzle needs to be supplied with high-pressure air and water. To that end, for example, as shown in FIG. 5, a compressor and a pump are used to supply high pressure air and water. FIG. 5 shows a two-fluid mist nozzle 306 for spraying mist, a liquid supply path 305 for supplying a liquid to the two-fluid mist nozzle 306, and an air supply path 304 for supplying air to the two-fluid mist nozzle 306. In the example of a spray system composed of a liquid pump 303 for producing a high-pressure liquid, a compressor 302 for generating high-pressure air, and a liquid tank 301 for supplying a liquid to the liquid pump 303. is there.

Japanese Unexamined Patent Publication No. 2000-107651 Japanese Unexamined Patent Publication No. 2001-137747

However, in the case of the above-mentioned prior art, water having a temperature lower than the temperature of the air in the external environment is supplied to the two-fluid mist nozzle, and this water is sprayed from the spray holes, so that the mist does not evaporate in a short time. There is. In this case, the mist tends to fall on the road surface before it evaporates, and therefore the effect of heat of vaporization cooling by the mist is reduced.

The present invention solves the above problems, and an object of the present invention is to provide a cooling device having a short evaporation time of the ejected mist.

In order to solve the conventional problems, the cooling device of the present invention has a two-fluid mist nozzle, a water path through which water flows toward the two-fluid mist nozzle, and compression at a temperature higher than that of the water toward the two-fluid mist nozzle. comprising an air path through which the air flows, and a heat exchange unit that had a row of heat exchanger to raise the temperature of the water between the hot compressed air flowing through the air path with the water flowing through the water passage.

According to the configuration of the present invention, heat exchange is performed between the high-temperature compressed air and water in the heat exchange section, so that the temperature of the mist ejected from the two-fluid mist nozzle rises. Therefore, the evaporation time of the ejected mist is shortened.

According to the present invention, the evaporation time of the mist is shortened, and the mist can be completely evaporated before falling on the road surface. Therefore, the amount of temperature decrease can be increased. Moreover, the cooling effect can be obtained quickly.

The figure which shows the structural example of the cooling apparatus which concerns on this embodiment. The figure which shows the example of the psychrometric chart which concerns on this embodiment Cross-sectional view of an internally mixed two-fluid mist nozzle Cross-sectional view of an externally mixed two-fluid mist nozzle Diagram of a spray system that uses a compressor and pump to supply high pressure air and water

In the first invention, the cooling device includes a two-fluid mist nozzle, a water path through which water flows toward the two-fluid mist nozzle, and an air path through which compressed air having a temperature higher than that of the water flows toward the two-fluid mist nozzle. A heat exchange unit that exchanges heat between water flowing through the water path and compressed air having a temperature higher than that of the water flowing through the air path is provided.

As a result, in the heat exchange section, heat is exchanged between the compressed air having a temperature higher than that of water and the water, so that the temperature of the mist ejected from the two-fluid mist nozzle rises. Therefore, the evaporation time of the ejected mist is shortened.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to this embodiment.

[Constitution]
FIG. 1 shows a configuration example of the cooling device according to the first embodiment.

The cooling device includes a two-fluid mist nozzle 6, a water path 8, an air path 7, a heat exchange section 2, a compressor 1, a pump 3, a first valve 4, a second valve 5, and condensed water. A collection unit 9 is provided.

The pump 3 is provided upstream of the water path 8 and supplies high-pressure water to the water path 8. The pump 3 is an example for supplying high-pressure water, and high-pressure water may be supplied by another method. The water path 8 is finally connected to the two-fluid mist nozzle 6.

The compressor 1 is provided upstream of the air path 7, and supplies compressed air (hereinafter referred to as “high temperature compressed air”) having a temperature higher than that of the water flowing through the water path 8 to the air path 7. The compressor 1 is an example for supplying high-temperature compressed air, and high-temperature compressed air may be supplied by another method. The air path 7 is finally connected to the two-fluid mist nozzle 6.

The water path 8 and the air path 7 are configured to pass through the heat exchange section 2 on the way to reach the two-fluid mist nozzle 6. The heat exchange unit 2 is a mechanism for exchanging heat between the water flowing through the water path 8 and the high-temperature compressed air flowing through the air path 7.

The heat exchange unit 2 has, for example, a double pipe structure in which the pipe of the water passage 8 covers the pipe of the air passage 7. In this case, the high-temperature compressed air passing through the pipe of the air path 7 exchanges heat with the water passing through the pipe of the water path 8 via the pipe. Therefore, the material of the tube of the air path 7 may be one having a high thermal conductivity such as copper or aluminum. As a result, efficient heat exchange can be performed. Further, in the heat exchange unit 2, the outer peripheral surface of the pipe of the air path 7 may be configured to increase the heat transfer area such as fins. As a result, more efficient heat exchange can be performed.

Further, the heat exchange unit 2 may be configured to be able to cool the compression mechanism of the compressor 1. As a result, the volumetric efficiency is improved, the discharge flow rate of the compressor 1 can be increased, and the power consumption can be reduced.

The first valve 4 is provided between the heat exchange unit 2 and the two-fluid mist nozzle 6 on the air path 7. By adjusting the first valve 4, the amount of air flowing through the air path 7 can be adjusted.

The second valve 5 is provided between the heat exchange unit 2 and the pump 3 on the water path 8. By adjusting the second valve 5, the amount of water flowing through the water path 8 can be adjusted.

By adjusting the first and second valves 4 and 5, the fluid can flow at a relatively high density in each path, and thus the flow velocity can be reduced and the pipe pressure loss can be reduced. The first and second valves 4 and 5 may not be provided.

The condensed water recovery unit 9 is provided between the heat exchange unit and the two-fluid mist on the air path 7. When the condensed water recovery unit 9 is cooled by the heat exchange unit 2 and the air generates condensed water, the condensed water recovery unit 9 recovers the condensed water and prevents the condensed water from entering the two-fluid mist nozzle 6. The condensed water recovery unit 9 is, for example, a pressure tank, a cyclone separator, or the like. The condensed water recovery unit 9 may not be provided.

[motion]
Next, the operation and operation of the cooling device configured as described above will be described with reference to FIGS. 1 and 2.

The compressor 1 boosts the air and supplies high-temperature compressed air to the air path 7. The pump 3 supplies high-pressure water to the water path 8.

In the heat exchange unit 2, the high-temperature compressed air flowing through the air path 7 and the water flowing through the water path 8 exchange heat. As a result, the temperature of the high-temperature compressed air is lowered and the temperature of the water is raised. The air and water that have undergone heat exchange in this way are supplied to the two-fluid mist nozzle 6.

When the two-fluid mist nozzle 6 is of the internal mixing type as shown in FIG. 3, the supplied water is crushed and refined by the jet of the supplied compressed air in the internal gas-liquid mixing unit 103. Then, the finely divided water is sprayed from the spray hole 104 together with the compressed air.

Here, heat exchange is also performed between water and compressed air in the gas-liquid mixing section 103. However, since water and compressed air are mixed and flow to the spray hole l04, the relative velocity difference between water and compressed air is small. Therefore, the heat transfer coefficient at this time is small. Further, since the distance from the mixing of water and compressed air in the gas-liquid mixing unit 103 to reaching the spray hole 104 is extremely short, the time for heat exchange between water and compressed air is also extremely short. Therefore, the heat exchange between water and compressed air performed in the two-fluid mist nozzle 6 has almost no effect.

Further, when the two-fluid mist nozzle 6 is an external mixing type as shown in FIG. 4, since water and compressed air are ejected through separate paths, heat exchange between water and air is hardly performed. That is, regardless of whether the two-fluid mist nozzle 6 according to the present embodiment is an internal mixing type or an external mixing type, the heat exchange between water and compressed air inside the two-fluid mist nozzle 6 is heat exchange. It has almost no effect on the heat exchange in part 2.

Next, the operation of the cooling device according to the present embodiment will be further described with reference to the example of the psychrometric chart of FIG.

In FIG. 2, the point 25 shows the state of the outside air (hereinafter referred to as “pre-mixing air”) before the air ejected from the two-fluid mist nozzle 6 is mixed.

Point 23 indicates the state of the air after the air ejected from the two-fluid mist nozzle 6 according to the prior art is mixed with the air before mixing.

Point 21 indicates the state of the air after the air ejected from the two-fluid mist nozzle 6 according to the present embodiment is mixed with the air before mixing.

The dry-bulb temperature of the point 21 according to the present embodiment is lower than that of the point 23 according to the prior art. This is because, in the present embodiment, the amount of heat of the compressed air ejected from the two-fluid mist nozzle 6 is taken away by the water in the heat exchange unit 2.

When the mist is ejected into the mixed air indicated by the points 21 and 23 and the mist evaporates, the states of the points 21 and 23 change in the direction of approaching the saturated water vapor line H on the enthalpy lines 26 and 27, respectively. Finally, the states 22 and 24 at the intersection of the enthalpy lines 26 and 27 and the saturated water vapor line H are obtained.

As shown in FIG. 2, the dry-bulb temperature T in the mixed air state 22 after mist evaporation according to the present embodiment is higher than the dry-bulb temperature T'in the mixed air state 24 after mist evaporation according to the prior art. It gets lower. As described above, according to the present embodiment, it is possible to increase the amount of cooling by the heat of vaporization cooling of the mist when the temperature of the air before mixing is used as a reference.

Further, the mist ejected from the nozzle receives heat from the high-temperature compressed air in the heat exchange unit 2 and has a temperature higher than that of the air before mixing, so that the mist is in a state of being easily evaporated.

Therefore, the time until the mist ejected from the two-fluid mist nozzle 6 evaporates is shortened, and the mist evaporates before it finishes falling on the road surface, so that the cooling effect is increased.

For example, in the summer, when the dry-bulb temperature of the air before mixing is 35 degrees and the temperature of the water supplied by the pump 3 is 25 degrees, the operation is as follows.

The water supplied from the pump 3 is 25 degrees, but the heat exchange section takes heat from the high-temperature compressed air, and the water temperature becomes higher than the dry-bulb temperature of the air before mixing of 35 degrees. That is, water having a temperature higher than 35 degrees is supplied to the two-fluid mist nozzle 6. Therefore, the mist ejected from the two-fluid mist nozzle 6 evaporates in a short time. Therefore, in the present embodiment, the amount of temperature decrease due to the heat of vaporization cooling of the mist increases as compared with the conventional technique in which the mist tends to fall on the road surface without evaporating.

The high-temperature compressed air supplied from the compressor 1 exceeds 100 degrees, but the amount of heat is taken away by water in the heat exchange unit 2 and the temperature becomes 40 degrees or less. That is, compressed air of 40 degrees or less is supplied to the two-fluid mist nozzle 6. Therefore, the compressed air ejected from the two-fluid mist nozzle 6 hardly raises the dry-bulb temperature of the air before mixing. Therefore, the amount of temperature decrease in the present embodiment is further increased as compared with the conventional technique of ejecting high-temperature compressed air.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention.

The present invention is suitable for use in a cooling device that cools an outdoor space by ejecting mist into the outdoor space.

1 Compressor 2 Heat exchanger 3 Pump 4 1st valve 5 2nd valve 6 2 Fluid mist nozzle 7 Air path 8 Water path 9 Condensed water recovery device

Claims (3)

Two-fluid mist nozzle and
The water path through which water flows toward the two-fluid mist nozzle,
An air path through which compressed air hotter than water flows toward the two-fluid mist nozzle,
There row heat exchange with the hot compressed air than the water flowing through the air path with the water flowing through the water passage, and a heat exchanger to raise the temperature of the water,
Cooling system. Compressed air, which is hotter than the water, is supplied by the compressor.
The cooling device according to claim 1. A first valve that regulates the amount of air flowing through the air path,
A second valve for adjusting the amount of water flowing in the water path is further provided.
The cooling device according to claim 1 or 2.

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