JP6957308B2 - Air conditioning system - Google Patents

Description

The present invention relates to an air conditioning system that supplies and ventilates air into a target space.

In recent years, an air supply system called a sock duct has been increasingly adopted as air conditioning equipment for a target space such as a clean room. The sock duct has, for example, a cloth cylindrical or semi-cylindrical sock body. One end of the sock body is closed and the other end has an opening, and an air supply device such as a fan is connected to this opening. Gas is sent to the sock body by this air supply device, and the sock body supplies air to the target space.

The sock duct emits a breeze by exuding the gas supplied from a large number of small holes in the sock body. Therefore, since the gas supplied from the sock duct spreads uniformly in wind speed and direction, for example, there are problems such as direct wind hitting the worker, drying of the surface of the work object such as food, and dust and dust flying around. Is expected to be resolved.

Japanese Unexamined Patent Publication No. 2009-074702 Japanese Unexamined Patent Publication No. 2013-040697

Here, the sock duct is a technology focusing on the air supply performance, and is not a technology that directly contributes to the improvement of the ventilation performance of the target space. Since the gas supplied from the socks duct has a uniform wind speed and direction, the airflow distribution in the target space formed by the socks duct is different from that of the gas supplied from the conventional gas outlet. However, what kind of airflow the gas supplied from the sock duct follows to the exhaust port has not yet been examined.

As a result of examining the airflow performance and ventilation performance in the target space when the socks duct is used as the air supply system, the inventors of the present invention have found that a stagnation has occurred in the target space. If there is a stagnation in the target space, the ventilation performance may deteriorate and dust, dust, etc. may accumulate in the target space. Therefore, there is a risk of reducing the cleanliness of the target space.

The present invention has been proposed to solve the problems of the prior art as described above. The purpose is to provide an air conditioning system with excellent ventilation performance.

In order to achieve the above object, the air conditioning system of the present invention has the following features.
(1) It has an air supply system that supplies gas to the target space and an exhaust system that discharges gas in the target space, and the target space includes a floor surface, a wall surface rising from the side of the floor surface, and a wall surface. a space defined by a ceiling surface opposed to the floor, the air supply system includes a diffuser of semi-cylindrical having a plurality of small holes, and the air supply device for supplying gas to the diffuser, has, the exhaust system comprises an exhaust port, and a discharge device for sucking gas from the exhaust port, the diffuser is provided along the end portion of the ceiling surface, the end portion The exhaust port is provided on the wall surface orthogonal to the other end facing the one end of the ceiling surface so as to extend in the height direction, and has a length corresponding to the above. It has a length corresponding to the side.

(2) pre-Symbol exhaust port, provided along the other end portion opposite to one end portion of the ceiling surface, may have a length corresponding to the other end.

(4) The exhaust port on the wall surface may be provided in the central portion of the wall surface so as to extend in the height direction.

(5) The exhaust port on the wall surface may be provided at the end of the wall surface so as to extend in the height direction.

(6) It has an air supply system that supplies gas to the target space and an exhaust system that discharges gas in the target space, and the target space includes a floor surface, a wall surface rising from the side of the floor surface, and a wall surface. It is a space defined by a floor surface and a ceiling surface facing the floor surface, and the air supply system includes a semi-cylindrical diffuser having a plurality of small holes, an air supply device that supplies gas to the diffuser, and an air supply device. The exhaust system has an exhaust port and an exhaust device that sucks gas from the exhaust port, and the diffuser has the two sides at the center of two facing sides of the ceiling surface. It is provided in orthogonal directions and has a length corresponding to the distance between the two sides, and the exhaust port is high at both ends of each of the two wall surfaces facing each other via the peripheral surface of the diffuser. It provided so as to extend in a direction to have a length corresponding to the height direction of the side of the wall.

(7) The exhaust port may be divided into a plurality of sections, and an opening amount adjusting mechanism for adjusting the opening amount of the sections may be provided.

According to the present invention, it is possible to provide an air conditioning system having excellent ventilation performance.

It is a block diagram which shows an example of the air-conditioning system which concerns on 1st Embodiment. It is a block diagram which shows an example of the conventional air-conditioning system. It is the result of analyzing the airflow in the conventional air-conditioning system, (a) shows the airflow distribution, and (b) shows the SVE-3 distribution. It is the result of analyzing the airflow in the air-conditioning system which concerns on 1st Embodiment, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is the result of analyzing the airflow in the air-conditioning system of the comparative example, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is a block diagram which shows an example of the air-conditioning system which concerns on 2nd Embodiment. It is the result of analyzing the airflow in the air-conditioning system which concerns on 2nd Embodiment, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is a block diagram which shows an example of the air-conditioning system which concerns on the modification of the 2nd Embodiment. It is the result of analyzing the airflow in the air-conditioning system which concerns on the modification of 2nd Embodiment, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is a block diagram which shows an example of the air-conditioning system which concerns on 3rd Embodiment. It is the result of analyzing the airflow in the air-conditioning system which concerns on 3rd Embodiment, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is the result of analyzing the airflow in the air conditioning system which concerns on a comparative example, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is a block diagram which shows an example of the air-conditioning system which concerns on 4th Embodiment. It is the result of analyzing the airflow in the air-conditioning system which concerns on 4th Embodiment, (a) and (c) show the SVE-3 distribution, and (b) and (d) show the airflow distribution. It is a block diagram which shows an example of the air-conditioning system which concerns on other embodiment. It is a block diagram which shows an example of the air-conditioning system which concerns on other embodiment.

[First Embodiment]
[1. composition]
An embodiment of the air conditioning system according to the present invention will be described with reference to the drawings. The air conditioning system includes an air supply system that supplies gas to the target space and an exhaust system that discharges the gas in the target space. The air supply system includes a semi-cylindrical diffuser having a plurality of small holes and an air supply device such as a fan that supplies gas to the diffuser. The exhaust system includes an exhaust port provided on the wall surface or ceiling surface of the target space, and an exhaust device such as a fan that sucks gas from the exhaust port.

As shown in FIG. 1, the target space S is a rectangular parallelepiped space. The target space S is a space defined by the floor surface s1, the four wall surfaces s2 rising vertically from the four sides of the floor surface s1, and the ceiling surface s3 facing the floor surface s1. The shape of the target space S is not limited to a rectangular parallelepiped, and may be the shape of an actual clean room or the like. The air conditioning system has a diffuser 1 provided on the ceiling surface s3 and an exhaust port 2 provided on the ceiling surface s3.

(Diffuse)
The diffuser 1 is formed by forming a cloth such as a non-woven fabric having a plurality of small holes into a semi-cylindrical bag body in which one end is closed and the other end has an opening. The diffuser 1 is suspended from the ceiling surface s3 of the target space by a wire or the like. An air supply device such as a fan is connected to the opening of the diffuser 1, and the gas is supplied to the inside of the diffuser 1.

As the diffuser 1, a sock duct having a semi-cylindrical sock body can be used. Alternatively, a semicircular punching metal may be installed as the diffuser 1 with respect to the existing outlet. The diffuser 1 installed in the existing outlet is not limited to the punching metal, and if it can be formed into a semi-cylindrical shape, it can be formed by using a material having many small holes such as a non-woven fabric. can.

The diffuser 1 is provided along one end of the ceiling surface s3 of the target space S. In the example of FIG. 1, in the rectangular ceiling surface s3, the diffuser 1 is provided in the vicinity of one side of the short side forming the ceiling surface s3. However, the diffuser 1 may be provided in the vicinity of one side of the long side forming the ceiling surface s3.

Further, the diffuser 1 has a length corresponding to one end of the ceiling surface s3 provided along the diffuser 1. In the example of FIG. 1, the diffuser 1 has a length corresponding to the short side forming the ceiling surface s3. The corresponding length can be regarded as the same length, but in actual installation, there are few cases where the length of the diffuser 1 and the length of one end of the ceiling surface s3 are exactly the same. Therefore, the diffuser 1 is often formed so as to be slightly shorter than one end of the ceiling surface s3. However, the diffuser 1 needs to have a sufficient length for the gas supplied from the diffuser 1 to spread uniformly inside the target space S.

(exhaust port)
The exhaust port 2 is an opening used for discharging the gas inside the target space S. The exhaust port 2 is provided along the other end of the ceiling surface s3 of the target space S, which faces the other end of the diffuser 1. In the example of FIG. 1, in the rectangular ceiling surface s3, the exhaust port 2 is provided in the vicinity of the other side of the short side forming the ceiling surface s3. However, the exhaust port 2 may be provided in the vicinity of the other side of the long side forming the ceiling surface s3.

Further, the exhaust port 2 has a length corresponding to the other end of the ceiling surface s3 provided along the exhaust port 2. In the example of FIG. 1, the exhaust port 2 has a length corresponding to the short side forming the ceiling surface s3. The corresponding length can be regarded as the same length, but in actual installation, there are few cases where an opening having exactly the same length as the end portion is provided on the ceiling surface s3.

Therefore, the exhaust port 2 is often formed so as to be slightly shorter than the other end of the ceiling surface s3. However, the exhaust port 2 needs to have a sufficient length for the gas supplied from the diffuser 1 to become a uniform flow and to be discharged from the inside of the target space S. The uniform flow means that the airflow generated inside the target space S varies and the gas finally heads toward the exhaust port 2 even if it is not in one direction, and the state in which the occurrence of stagnation is suppressed is suppressed. show. An exhaust device such as a fan that sucks gas from the exhaust port is connected to the exhaust port 2 as described above.

A circulation path may be provided to return the gas sucked from the exhaust port 2 to the diffuser 1. A fan filter unit having a blower and a high-performance filter may be provided in the circulation path, and the high-performance filter may be used to remove contaminants contained in the gas. The gas sucked from the exhaust port 2 may be re-supplied into the target space S after improving the degree of cleaning.

[2. motion]
(Operation of air supply system)
When the air conditioning system is in operation, the air supply system performs the following operations. That is, when the air supply device supplies the gas to the diffuser 1, the supplied gas is diffused by the diffuser 1 and supplied to the inside of the target space S. As described above, the semi-cylindrical diffuser 1 having a plurality of small holes is provided along one end of the ceiling surface s3 of the target space S, and has a length corresponding to the one end. Therefore, the gas supplied to the inside of the target space S is diffused by the diffuser 1, and the wind speed and the wind direction of the gas spreading inside the target space S become uniform.

(Operation of exhaust system)
In addition, the exhaust system performs the following operations. That is, the ventilation device sucks the gas inside the target space S through the exhaust port 2. As described above, the exhaust port 2 is provided along the other end of the ceiling surface s3 of the target space S, and has a length corresponding to the other end. Therefore, the gas supplied to the inside of the target space S by the diffuser 1 becomes a uniform flow, goes from the diffuser plate 1 to the exhaust port 2, and is discharged through the exhaust port 2.

[3. simulation]
The gas flow when the air conditioning system of the present embodiment as described above was operated was analyzed. First, for comparison, the results of analyzing the gas flow when operating a conventional air conditioning system are shown below.

(Conventional air conditioning system)
Some conventional air conditioning systems have an air supply system and an exhaust system shown in FIG. In the example of FIG. 2, the target space S is a room having a length (x) of 10 m, a depth (y) of 5 m, and a height (z) of 2.5 m. As the diffuser 1, a semi-cylindrical sock body having a radius of 0.5 m was used. The diffuser 1 is arranged in a direction orthogonal to the longitudinal direction in the central portion of the ceiling surface s3 in the longitudinal direction. The diffuser 1 has a length corresponding to the short side forming the ceiling surface s3.

One exhaust port 2 is provided on each of the two wall surfaces s2 facing each other via the peripheral surface of the diffuser 1. The two exhaust ports 2 are square openings located in the central portion of the wall surface s2 in the depth direction, and are provided so as to face each other. That is, the exhaust port 2 does not have a length corresponding to the side of the wall surface s2. The total area of the exhaust port 2 was ^{0.5 m 2.}

In the conventional air conditioning system as described above, the airflow when the wind speed from the diffuser 1 was 1.0 m / s was analyzed. FIG. 3A shows the airflow distribution, and FIG. 3B shows the SVE-3 distribution. SVE refers to a ventilation performance evaluation index (Scale of Ventilation Efficiency), and SVE-3, which is one of the six types of evaluation indexes, is a value indicating the local average air age used in the ventilation field. The air age corresponds to the time it takes for the fresh air introduced into the room to reach a certain point from the air supply port. Therefore, the lower the value of SVE3, the smoother the gas is discharged from the exhaust port 2.

3 (a) and 3 (b) show the airflow distribution and the SVE-3 distribution in a cross section having a depth of y = 2.5 m in which the exhaust port 2 is provided. From FIG. 3A, the gas radially supplied from the diffuser 1 was flowing toward the discharge port 2. However, in the vicinity of the angle formed by the ceiling surface s3 and the wall surface s2 in the upper portion of the discharge port 2, an airflow colliding with the airflow discharged from the diffuser 1 was confirmed. Stagnation occurred in the collision part, and as is clear from FIG. 3 (b), SVE-3 in the stagnation part showed 2.0 or more. That is, a stagnation has occurred. The average value of SVE-3 was 0.63, and the ventilation performance was deteriorated.

(Air conditioning system of this embodiment)
Next, in the air conditioning system of the present embodiment, the air flow was analyzed. The analysis result shown in FIG. 4 is based on the analysis using the air conditioning system shown in FIG. The target space S in which the air conditioning system used in the analysis is installed is a room having a length (x) of 6 m, a depth of (y) of 3 m, and a height (z) of 2.5 m. As the diffuser 1, a semi-cylindrical sock body having a radius of 0.4 m was used. The exhaust port 2 has an opening having a length of 120 mm and a depth of 3000 mm.

In the above air conditioning system, the airflow when the airflow speed from the diffuser 1 is 0.1 m / s, the air supply air volume is 1357.1 m ³ / h, and the intake air velocity of the exhaust port 2 is 1.0 m / s. Analyzed. FIGS. 4 (a) and 4 (b) show the airflow distribution and the SVE-3 distribution in a cross section having a depth of y = 1.5 m, which is the central portion of the target space S in the lateral direction. 4 (c) and 4 (d) show the airflow distribution and the SVE-3 distribution in a cross section with a depth of y = 0.5 m.

From FIGS. 4 (b) and 4 (d), the gas radially supplied from the diffuser 1 became a uniform flow and flowed toward the discharge port 2. No airflow colliding with the airflow emitted from the diffuser 1 was confirmed. That is, the occurrence of stagnation was suppressed. As is clear from FIGS. 4A and 4C, the value of SVE-3 is also low in the entire target space S. The average value of SVE-3 was 0.55 for both the cross section with a depth of y = 1.5 m and the cross section with a depth of y = 0.5 m, confirming an improvement in ventilation performance.

The same analysis as above was performed when the length of the exhaust port 2 was 240 mm and the intake air speed was 0.5 m / s, and when the length was 1200 mm and the intake air speed was 0.1 m / s. The analysis results were the same as when the exhaust port 2 having a length of 120 mm was used, and the average value of SVE-3 was 0.55 in both cases.

(Comparison example)
As a comparative example, in the air conditioning system of the present embodiment, the case where the diffuser 1 is used as a cylindrical socks duct body having a radius of 0.2 m was analyzed. 5 (a) and 5 (b) show the airflow distribution and the SVE-3 distribution in a cross section having a depth of y = 2.5 m, which is the central portion of the target space S in the lateral direction. 5 (c) and 5 (d) show the airflow distribution and the SVE-3 distribution in a cross section with a depth of y = 0.5 m.

From FIGS. 5 (b) and 5 (d), the gas radially supplied from the diffuser 1 was flowing toward the discharge port 2. However, in most of the space on the exhaust port 2 side, an airflow colliding with the airflow emitted from the diffuser 1 was confirmed. At the collision part, stagnation occurred, and as is clear from FIGS. 5 (a) and 5 (c), SVE-3 showed 2.0 or more. That is, a stagnation has occurred. The average value of SVE-3 was 0.91 in the cross section with a depth of y = 1.5 m and 1.05 in the cross section with a depth of y = 0.5 m, and the ventilation performance was deteriorated.

It is considered that there are the following causes for the deterioration of the ventilation performance when the cylindrical diffuser 1 is used. When the cylindrical diffuser 1 is used, gas is supplied along the peripheral surface of the diffuser 1. Therefore, the gas toward the upper side of the diffuser 1 is supplied. Since the diffuser 1 is suspended from the ceiling surface s3, turbulence is generated above the diffuser 1. As a result, it is considered that excess air forms an environment in which turbulence and collisions are likely to occur. Further, as is clear from FIGS. 5 (b) and 5 (d), the flow velocities of the gas flowing on the ceiling surface s3 side of the target space S and the gas flowing on the floor surface s1 side are different. It is considered to be one of the causes of.

[4. Action effect]
The effects of the air conditioning system of the present embodiment as described above are as follows.
(1) It has an air supply system that supplies gas to the target space and an exhaust system that discharges gas in the target space, and the target space has a floor surface s1 and a side perpendicular to the side of the floor surface s1. It is a space defined by the extending wall surface s2 and the ceiling surface s3 facing the floor surface s1, and the air supply system applies gas to the semi-cylindrical diffuser 1 having a plurality of small holes and the diffuser 1. The exhaust system has an exhaust port 2 and an exhaust device that sucks gas from the exhaust port 2, and the diffuser 1 is provided on the ceiling surface s3 and has a ceiling surface. The exhaust port 2 has a length corresponding to the side of the ceiling surface s3 or the wall surface s2, and has a length corresponding to the side of the ceiling surface s3 or the wall surface s2.

With the above configuration, the exhaust port 2 discharges the gas supplied in a planar manner by the diffuser 1 in a planar manner. Therefore, the gas supplied from the diffuser 1 can be made into a uniform flow and flow toward the exhaust port 2, and the occurrence of stagnant flow can be suppressed.

(2) The diffuser 1 is provided along one end of the ceiling surface s3, has a length corresponding to the one end, and the exhaust port 2 is the other end facing the one end of the ceiling surface s3. It is provided along the above and has a length corresponding to the other end.

With the above configuration, it is possible to form a uniform flow flowing from one end to the other end of the target space S, and gas can be efficiently discharged from the inside of the target space S. In this case, the wind speed of the gas supplied from the diffuser 1 becomes gentle in the central portion of the target space S. Therefore, it is possible to prevent a direct wind from hitting the worker or the work object. Therefore, it is possible to prevent the operator from feeling uncomfortable and preventing the work object from drying and changing the quality.

Further, the degree of cleaning on the one end side where the diffuser 1 is provided is the highest, and a gradation of the degree of cleaning is formed toward the other end side where the exhaust port 2 is provided. For example, when the target space S is a changing room which is an ancillary facility of the clean room, an entrance to the clean room is provided on the wall surface s2 on the diffuser 1 side, and the changing room is entered on the wall surface s2 on the exhaust port 2 side from a corridor or the like. The entrance to the room will be provided. Then, the worker enters the room from the corridor side, and the pollutants adhering to the worker are gradually removed by the time the worker enters the clean room, and the state can be kept in the most cleaned state when entering the clean room. .. Therefore, opening and closing the door to the clean room can prevent contaminants in the changing room from leaking to the clean room side.

Further, by installing the exhaust port 2 on the ceiling surface s3, it is not necessary to provide an exhaust system on the wall surface s2. Therefore, the installation location of the door of the target space S and the arrangement of the equipment inside the target space S are not restricted by the exhaust system. Therefore, the degree of freedom in designing the target space S can be improved.

[Second Embodiment]
[1. composition]
The configuration of the air conditioning system of the second embodiment is basically the same as that of the first embodiment. However, in the present embodiment, as shown in FIG. 6, the exhaust port 2 is provided on the wall surface s2 orthogonal to the other end facing the one end where the diffuser 1 is provided on the ceiling surface s3. The exhaust port 2 is provided so as to extend in the central portion of the wall surface 2s in the direction orthogonal to the ceiling surface s3, that is, in the height direction. The exhaust port 2 has a length corresponding to the side of the wall surface s2 in the height direction.

[2. simulation]
Next, in the air conditioning system of the present embodiment, the air flow was analyzed. The analysis result shown in FIG. 7 is based on the analysis using the air conditioning system shown in FIG. The target space S in which the air conditioning system used in the analysis is installed is a room having a length (x) of 6 m, a depth of (y) of 3 m, and a height (z) of 2.5 m. As the diffuser 1, a semi-cylindrical sock body having a radius of 0.4 m was used. The exhaust port 2 has an opening having a height of 2500 mm and a depth of 144 mm.

In the above air conditioning system, the airflow when the airflow speed from the diffuser 1 is 0.1 m / s, the air supply air volume is 1357.1 m ³ / h, and the intake air velocity of the exhaust port 2 is 1.0 m / s. Analyzed. 7 (a) and 7 (b) show the airflow distribution and the SVE-3 distribution in a cross section having a depth of y = 1.5 m, which is the central portion of the target space S in the lateral direction. 7 (c) and 7 (d) show the airflow distribution and the SVE-3 distribution in a cross section with a depth of y = 0.5 m.

From FIG. 7B, the airflow that collides with the airflow emitted from the diffuser 1 at the corner portion formed by the ceiling surface s3 and the wall surface s2 on the exhaust port 2 side in the central portion of the target space S in the lateral direction. Was confirmed. However, these collision airflows were generated in the vicinity of the exhaust port 2. Therefore, it is considered that the exhaust gas is discharged from the exhaust port relatively smoothly. This point is clear from the fact that the portion of SVE-3 showing 2.0 or more in FIG. 7A is less than that of the conventional example. The average value of SVE3 in the cross section with a depth of y = 1.5 m was 0.65.

Further, in FIG. 7D, the gas radially supplied from the diffuser 1 became a uniform flow and flowed toward the discharge port 2. Almost no airflow colliding with the airflow emitted from the diffuser 1 was confirmed. That is, the occurrence of stagnation was suppressed. As is clear from FIG. 7C, the value of SVE-3 is also low in the entire target space S. The average value of SVE3 in the cross section with a depth of y = 0.5 m was 0.57.

From the analysis results of FIGS. 7A to 7D, in the air conditioning system of the present embodiment, although the airflow collides in the vicinity of the exhaust port 2, the ventilation efficiency improves as the distance from the exhaust port 2 increases. It turned out. That is, it can be seen that the gas is smoothly ventilated except in the vicinity of the exhaust port 2. From the fact that the average value of SVE3 in the cross section with the depth y = 0.5 m is 0.57, it was found that the target space S as a whole has better ventilation efficiency than the conventional example.

[3. Action effect]
The effects of the air conditioning system of the present embodiment as described above are the same as those of the above embodiment, and specifically, there are the following effects. In the air conditioning system of the present embodiment, the diffuser 1 is provided along one end of the ceiling surface s3 and has a length corresponding to the one end, and the exhaust port 2 is provided with one end of the ceiling surface s3. It is provided in the central portion of the wall surface s2 orthogonal to the other end facing each other so as to extend in the height direction, and has a length corresponding to the side in the height direction of the wall surface s2.

With the above configuration, the gas supplied from the diffuser 1 can be made into an air flow close to a uniform flow. Therefore, the gas supplied from the diffuser 1 flows to the exhaust port 2 side. Even if a stagnation occurs, most of it is generated in the vicinity of the exhaust port 2, so that the air is smoothly discharged through the exhaust port 2. Therefore, the occurrence of stagnation can be suppressed.

[Modified example of the second embodiment]
[1. composition]
The configuration of the air conditioning system of the modified example of the second embodiment is basically the same as that of the second embodiment. However, in the present embodiment, as shown in FIG. 8, the exhaust port 2 is divided into a plurality of divisions 2a to 2d, and a mechanism for adjusting the opening amount is provided in each of the plurality of divisions. A punching metal or a shutter can be used as the opening amount adjusting mechanism. In the punching metal, the opening amount of the exhaust port 2 can be adjusted by changing the diameter of the punching.

In the example of FIG. 8, the exhaust port 2 is divided into four sections 2a to 2d having the same height. For example, when the height of the exhaust port 2 is 2500 mm, the height of one division is 625 mm. However, the number of divisions may be 2 or more, and the height of each division does not necessarily have to be the same. In the four categories 2a to 2d, the opening amount was changed according to the value of SVE-3 in each category obtained from the SVE-3 distribution in FIG. 7 (a).

Specifically, the opening amount of the division 2a closest to the ceiling surface s3 side, which had a value of SVE-3 of 0.81, was set to 100%. That is, the division 2a is not provided with the opening amount adjusting mechanism. Based on the value of SVE-3 in Category 2a and the opening amount, the calculation shown in FIG. 8 was performed to determine the opening amount in each Category 2b to 2d. An opening amount adjusting mechanism was provided so that the opening amounts of the respective categories 2a to 2d were as obtained. As described above, the higher the value of SVE-3, the larger the opening amount, so that more gas can be exhausted.

[2. simulation]
Next, the air flow was analyzed in the air conditioning system of the modified example of the second embodiment. The analysis result shown in FIG. 9 is based on the analysis using the air conditioning system shown in FIG. The conditions such as the air conditioning system and the wind speed and air volume used in the analysis are the same as those in the second embodiment except that the exhaust port 2 has the above configuration.

From the analysis results of FIGS. 9A to 9D, in the air conditioning system of the present embodiment, although the airflow collision occurs in the vicinity of the exhaust port 2, the ventilation efficiency is higher than that of the second embodiment. It turned out to be improving. That is, from the comparison of the airflow distributions of FIGS. 7 (b) and 7 (d) and FIGS. 9 (b) and 9 (d), it can be seen that the space where the gas collision occurs is narrowed in the modified example. Similarly, from the comparison of the SVE-3 distributions of FIGS. 7 (a) and 7 (a) and 9 (a) and 9 (c), the ventilation efficiency was improved in the modified example, and the SVE-3 was 2.0 or more. It can be seen that the part that becomes is decreasing. The average value of SVE-3 decreased from 0.65 in the cross section of depth y = 1.5 m to 0.62 in the second embodiment. In addition, the cross section with a depth of y = 0.5 m was 0.57, but it was reduced to 0.56. As is clear from the above, the ventilation efficiency was improved in the modified example as compared with the second embodiment.

[3. Action effect]
The effects of the air conditioning system of the present embodiment as described above are the same as those of the above embodiment, and specifically, there are the following effects. That is, in the modified example, the exhaust port 2 is divided into a plurality of sections, and an opening amount adjusting mechanism for adjusting the opening amount of the sections is provided.

With the above configuration, the larger the SVE-3 value, the larger the opening amount can be set, so that more gas can be exhausted from the lower ventilation efficiency category. Therefore, even when a gas collision occurs in the target space S, exhaust from the exhaust port 2 can be promoted. Therefore, the occurrence of stagnation can be suppressed more reliably.

[Third Embodiment]
[1. composition]
The configuration of the air conditioning system of the third embodiment is basically the same as that of the first embodiment. However, in the present embodiment, as shown in FIG. 10, the diffuser 1 is provided in the central portion of the two opposing sides of the ceiling surface s3 in a direction orthogonal to the two sides, and corresponds to the distance between the two sides. Has a length to do. Here, the diffuser 1 is arranged in the central portion of the ceiling surface s3 in the longitudinal direction in a direction orthogonal to the longitudinal direction. The diffuser 1 has a length corresponding to the short side forming the ceiling surface s3.

Further, the exhaust port 2 is provided so as to extend in a direction orthogonal to the ceiling surface s3, that is, in a height direction at both ends of each of the two wall surfaces s2 facing each other via the peripheral surface of the diffuser 1. That is, a total of four exhaust ports 2 are provided. The exhaust port 2 has a length corresponding to the side of the wall surface s2 in the height direction.

[2. simulation]
Next, in the air conditioning system of the present embodiment, the air flow was analyzed. The analysis result shown in FIG. 11 is based on the analysis using the air conditioning system shown in FIG. The conditions such as the air conditioning system and the wind speed and air volume used in the analysis are the same as those in the second embodiment except that the exhaust port 2 has the above configuration. The exhaust port 2 has an opening having a height of 2500 mm and a depth of 36 mm, respectively.

From FIGS. 11 (b) and 11 (d), gas collisions occur in the vicinity of the corner formed by the floor surface s1 and the wall surface s2 of the target space S and in the vicinity of the corner portion formed by the ceiling surface s3 and the wall surface s2. Was there. However, the space where the gas collision occurs is smaller than that of the conventional example. Similarly, from the SVE-3 distributions in FIGS. 11 (a) and 11 (c), it can be seen that the portion where SVE-3 is 2.0 or more is reduced and the ventilation efficiency is improved. The average value of SVE3 in the cross section with a depth of y = 0.5 m was 0.54, and the average value of SVE3 in the cross section with a depth of y = 1.5 m was 0.69. In the present embodiment, since the exhaust ports 2 extending in the height direction are provided at the four corners of the target space S, the gas can be discharged smoothly as compared with the conventional example even when a stagnation occurs. it is conceivable that.

(Comparison example)
As a comparative example, in the air conditioning system of the present embodiment, an analysis was performed on a case where the exhaust port 2 is formed shorter than the side of the wall surface s2 in the height direction. That is, the exhaust port 2 has an opening having a height of 900 mm and a depth of 10 mm, respectively, and the exhaust port 2 is formed only on the lower side of the wall surface s2.

From FIGS. 12 (b) and 12 (d), the collision of gas generated occurs in the vicinity of the corner formed by the floor surface s1 and the wall surface s2 of the target space S and in the vicinity of the corner portion formed by the ceiling surface s3 and the wall surface s2. It increased as compared with the third embodiment. In particular, since the exhaust port 2 is not formed on the upper side of the wall surface s2, the collision of gas in the vicinity of the corner formed by the ceiling surface s3 and the wall surface s2 has increased remarkably. From FIGS. 12 (a) and 12 (c), the value of SVE-3 in the vicinity of the corner formed by the ceiling surface s3 and the wall surface s2 is 2.0 or more, and the ventilation efficiency is lowered. As described above, it has been clarified that the ventilation efficiency is improved by setting the exhaust port 2 to have a length corresponding to the side of the wall surface s2 in the height direction.

[3. Action effect]
The effects of the air conditioning system of the present embodiment as described above are the same as those of the above embodiment, and specifically, there are the following effects. In the air conditioning system of the present embodiment, the diffuser 1 is provided in the central portion of the two opposing sides of the ceiling surface s3 in a direction orthogonal to the two sides, and has a length corresponding to the distance between the two sides. The exhaust port 2 is provided so as to extend in the height direction at both ends of each of the two wall surfaces s2 facing each other via the peripheral surface of the diffuser 1, and corresponds to the side in the height direction of the wall surface s2. Has a length.

With the above configuration, the gas supplied from the diffuser 1 can be made into an air flow close to a uniform flow. Therefore, the gas supplied from the diffuser 1 flows to the exhaust port 2 side. Even if a stagnation occurs, since the exhaust ports 2 extending in the height direction are provided at the four corners of the target space S, even if a stagnation occurs, the gas is smoother than in the conventional example. Can be discharged. Therefore, the occurrence of stagnation can be suppressed. Further, by arranging the diffuser 1 in the central portion of the target space S, the gas supplied from the diffuser 1 can be efficiently used.

[Fourth Embodiment]
[1. composition]
The configuration of the air conditioning system of the fourth embodiment is basically the same as that of the first embodiment. However, in the present embodiment, as shown in FIG. 13, the exhaust port 2 is, in addition to the exhaust port 2 provided on the ceiling surface s3, the other end portion facing the one end portion on the ceiling surface s3 where the diffuser 1 is provided. It is provided on the wall surface s2 orthogonal to the wall surface s2. The exhaust port 2 is provided so as to extend in the central portion of the wall surface 2s in the direction orthogonal to the ceiling surface s3, that is, in the height direction. The exhaust port 2 has a length corresponding to the side of the wall surface s2 in the height direction. That is, this embodiment is a combination of the exhaust port 2 of the first embodiment and the second embodiment.

[2. simulation]
Next, in the air conditioning system of the present embodiment, the air flow was analyzed. The analysis result shown in FIG. 14 is based on the analysis using the air conditioning system shown in FIG. The conditions such as the air conditioning system and the wind speed air volume used in the analysis are the same as those in the first embodiment except that the exhaust port 2 has the above configuration. The exhaust port 2 on the ceiling surface s3 has an opening having a length of 120 mm and a depth of 3000 m. Further, the exhaust port 2 of the wall surface s2 has an opening having a height of 2500 mm and a depth of 144 mm.

From FIGS. 14 (b) and 14 (d), the gas radially supplied from the diffuser 1 became a uniform flow and flowed toward the discharge port 2. No airflow colliding with the airflow emitted from the diffuser 1 was confirmed. That is, the occurrence of stagnation was suppressed. Similarly, as is clear from FIGS. 14 (a) and 14 (c), the value of SVE-3 is also low in the entire target space S. The average value of SVE-3 was 0.58 for a cross section with a depth of y = 1.5 m and 0.56 for a cross section with a depth of y = 0.5 m, confirming an improvement in ventilation performance.

[3. Action effect]
In the air conditioning system of the present embodiment as described above, the effects of both the first embodiment and the second embodiment can be obtained. That is, it is possible to form a uniform flow that flows from one end to the other end of the target space S, and the gas can be efficiently discharged from the inside of the target space S.

[Other embodiments]
In the fourth embodiment, as an example of combining the first embodiment and the second embodiment, the exhaust port 2 is provided in the central portion of the wall surface 2s. However, as shown in FIGS. 15 and 16, exhaust ports 2 extending in the height direction may be arranged at one end or both ends of the wall surface s2. Even with such an exhaust port 2, the same effect as that of the above embodiment can be obtained.

The combination of embodiments is not limited to the combination of the first embodiment and the second embodiment. That is, it is possible to appropriately combine the first to third embodiments.

S Target space s1 Floor surface s2 Wall surface s3 Ceiling surface 1 Diffuse body 2 Exhaust port 2a to 2d Classification

Claims (6)

It has an air supply system that supplies gas to the target space and an exhaust system that discharges the gas in the target space.
The target space is a space defined by a floor surface, a wall surface rising from the side of the floor surface, and a ceiling surface facing the floor surface.
The air supply system comprises a diffuser of semi-cylindrical having a plurality of small holes, and a gas supply device for supplying gas to the diffuser,
The exhaust system includes an exhaust port, and a discharge device for sucking gas from the exhaust port,
The diffuser is provided along one end of the ceiling surface and has a length corresponding to the one end.
The exhaust port is provided on the wall surface orthogonal to the other end portion facing the one end portion of the ceiling surface so as to extend in the height direction, and has a length corresponding to the height side of the wall surface. system. Before Symbol exhaust port, further provided along the other end portion opposite to one end portion of the ceiling surface, the air conditioning system of claim 1 having a length corresponding to the other end. The air conditioning system according to claim 1 or 2 , wherein the exhaust port on the wall surface is provided in the central portion of the wall surface so as to extend in the height direction. The air conditioning system according to claim 1 or 2 , wherein an exhaust port on the wall surface is provided at an end of the wall surface so as to extend in the height direction. It has an air supply system that supplies gas to the target space and an exhaust system that discharges the gas in the target space.
The target space is a space defined by a floor surface, a wall surface rising from the side of the floor surface, and a ceiling surface facing the floor surface.
The air supply system comprises a diffuser of semi-cylindrical having a plurality of small holes, and a gas supply device for supplying gas to the diffuser,
The exhaust system includes an exhaust port, and a discharge device for sucking gas from the exhaust port,
The diffuser is provided in the central portion of the two opposite sides of the ceiling surface in a direction orthogonal to the two sides, and has a length corresponding to the distance between the two sides.
The exhaust port is provided so as to extend in the height direction at both ends of each of the two wall surfaces facing each other via the peripheral surface of the diffuser, and has a length corresponding to the side in the height direction of the wall surface. Air conditioning system to have. The exhaust port is divided into a plurality of sections, and the exhaust port is divided into a plurality of sections.
The air conditioning system according to any one of claims 1 to 5, wherein an opening amount adjusting mechanism for adjusting the opening amount of the above-mentioned category is provided.

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