KR102627792B1 - Air conditioning system - Google Patents

Abstract

The present invention relates to an air conditioning system for cooling and heating in the indoor space of a building structure. The air conditioning system according to an embodiment of the present invention is installed on a ceiling panel adjacent to a wall of a building structure and directed in a direction opposite to the direction of the wall. a ventilation groove formed between the air supply diffuser and the wall to communicate the space between the slab of the building structure and the ceiling panel with the indoor space through which the air supply diffuser discharges air; And, an air supply duct on one side connected to the air supply diffuser, a ventilation duct on one side provided with a ventilation opening located between the slab and the ceiling panel, and an air conditioner connected to the other side of the air supply duct and the other side of the ventilation duct. do.

Description

Air conditioning system{AIR CONDITIONING SYSTEM}

The present invention relates to an air conditioning system that maintains the air in the indoor space of a building structure in a comfortable condition.

In modern society, it is common for many people to live densely in various buildings in urban areas, such as office spaces, residential apartments, public facilities such as schools, cultural facilities such as performance halls, and condominiums. Therefore, in order to maintain the health of occupants and improve work efficiency in these collective buildings, it is required to maintain appropriate indoor air quality.

However, since each person living in the same indoor space experiences different degrees of cold or heat, there is a problem in that it is difficult to maintain the indoor environment under conditions that satisfy everyone.

In addition, ventilation systems and air conditioning systems installed to maintain indoor air quality at appropriate levels supply air to indoor spaces or use ventilation devices or air conditioners to supply air to indoor spaces. A duct of considerable length is used to return it to the device. And as the length of the duct increases, the power required to transport air also increases. In other words, as the length of the duct becomes longer, not only does the required performance of the air supply fan or ventilation fan increase, but the noise generated thereby also increases.

Embodiments of the present invention provide an air conditioning system that not only minimizes the use of ducts relative to the size of the indoor space, but is also unobtrusive in appearance in the indoor space.

According to an embodiment of the present invention, an air conditioning system for performing cooling and heating in the indoor space of an architectural structure is installed on a ceiling panel adjacent to the wall of the architectural structure and discharges air toward the indoor space in a direction opposite to the direction of the wall. an air supply diffuser, a ventilation groove formed between the air supply diffuser and the wall to communicate a space between a slab of a building structure and the ceiling panel with an indoor space through which the air supply diffuser discharges air, and one side of the air supply diffuser is It includes an air supply duct connected to the air supply diffuser, a ventilation duct on one side provided with a ventilation opening located between the slab and the ceiling panel, and an air conditioner connected to the other side of the air supply duct and the other side of the ventilation duct.

In the air conditioning system described above, when the air supply diffuser discharges air in a horizontal direction opposite to the direction of the ventilation groove, the discharged air moves along the ceiling panel through the Coanda effect and is connected to the wall dividing the indoor space and the indoor space. It may be configured to circulate along the floor, move to the space between the ceiling panel and the slab through the ventilation groove, and then flow into the ventilation duct through the ventilation hole.

The air conditioning system may further include a ventilation grill coupled to the ventilation groove or disposed over the ventilation groove.

The indoor space of the architectural structure includes a plurality of rooms and a corridor connecting the plurality of rooms, wherein the air supply diffuser is installed on the ceiling panel so as to be adjacent to the hallway side wall for each of the plurality of rooms, and the ventilation A groove is formed between the air supply diffuser and the corridor side wall, the air supply duct is connected to the air supply diffuser installed in each of the plurality of rooms through the corridor, and the ventilation opening provided in the ventilation duct is connected to the plurality of rooms through the corridor. It can be installed in every room.

The indoor space of the building structure includes a plurality of rooms and a corridor connecting the plurality of rooms, the air supply diffuser is installed on the ceiling panel adjacent to the window side wall for each of the plurality of rooms, and the ventilation groove is formed between the air supply diffuser and the window side wall, the air supply duct is connected to the air supply diffuser installed in each of the plurality of rooms through the corridor, and the ventilation opening provided in the ventilation duct is connected to the plurality of rooms through the corridor. It can be installed in every room.

The air conditioning system may further include a ventilation auxiliary transfer fan installed on the window side wall to transfer air toward the ventilation groove.

Additionally, a curtain box may be formed on the ceiling panel adjacent to the window-side wall in each of the plurality of rooms, and the ventilation groove may be installed on one or more of the vertical and horizontal sides of the curtain box.

The air conditioner may be installed in a separately partitioned machine room from the indoor space of the building structure.

The ventilation groove may be formed continuously and long along one side of the ceiling panel.

The air supply diffuser has a lower part connected to the ceiling panel, a diffuser frame having a continuously elongated slot or a square-shaped outlet along one side of the ceiling panel, and is rotatably inserted into the interior of the diffuser frame, and is rotatably inserted into the diffuser frame according to the rotation angle. The wind direction of the air discharged from the outlet of the diffuser frame is adjusted, and a wind direction control drum is included, a portion of which protrudes from the outlet of the diffuser frame toward the indoor space to allow air to be discharged in a direction parallel to the ceiling panel. can do.

The air conditioning system may further include a ventilation grill installed in the ventilation groove. Additionally, one side of the ventilation grill may be supported by the diffuser frame of the air supply diffuser, and the other side of the ventilation grill may be supported by a support installed on the wall.

The wind direction control drum includes a hollow cylindrical drum body having a length in a direction parallel to the discharge port of the diffuser frame and continuously formed to be long along one side of the ceiling panel, and a drum body in the shape of a hollow cylinder in an area on a side of the drum body. It may include a plurality of intermittently formed linear airflow outlets along the longitudinal direction, and a plurality of linear airflow inlets intermittently formed parallel to the plurality of linear airflow outlets in another area of the side of the drum body opposite to the linear airflow outlets. You can.

When the wind direction control drum induces the discharge of air to the right to cause the Coanda effect, the left edge of the linear airflow outlet in the longitudinal reference cross section of the drum body is a vertical reference line passing through the center of the drum body. It protrudes to the right by a preset discharge angle, and when the wind direction control drum induces discharge of air in the left direction to cause the Coanda effect, the right edge of the linear airflow outlet in the longitudinal reference cross section of the drum body may protrude to the left by a preset discharge angle from the vertical reference line passing through the center of the drum body.

The preset discharge angle may fall within the range of 3 degrees to 15 degrees.

An opening angle of the linear airflow outlet in the longitudinal cross-section of the drum body may be within the range of 40 degrees to 60 degrees.

An airflow guide wall may be formed inside the drum body to suppress the generation of vortices while the air flowing into the plurality of linear airflow inlets moves to the plurality of linear airflow discharge ports.

The wind direction control drum may be configured to discharge the wind direction of the air discharged from the discharge port of the diffuser frame in a direction selected from downward, right, or left depending on the rotation angle, or to close the discharge port of the diffuser frame. there is.

According to an embodiment of the present invention, the air conditioning system can not only minimize the use of ducts compared to the size of the indoor space, but can also be installed so as not to be conspicuous in appearance in the indoor space.

1 is a plan view showing an air conditioning system according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view showing one of a plurality of rooms in which the air conditioning system of FIG. 1 is installed.
Figure 3 is an enlarged view of part A of Figure 2.
Figure 4 is an enlarged plan view showing the arrangement ecology of the ventilation grill and air supply diffuser used in the air conditioning system of Figure 1.
Figure 5 shows a state in which a ventilation grill is installed according to a modification of the first embodiment of the present invention.
Figure 6 is a cross-sectional view showing one of a plurality of rooms in which an air conditioning system according to a second embodiment of the present invention is installed.
FIG. 7 is an enlarged view of part B of FIG. 5.
Figure 8 is a cross-sectional view showing one of a plurality of rooms in which an air conditioning system according to a third embodiment of the present invention is installed.
Figure 9 is an enlarged cross-sectional view of a part of the air conditioning system according to the fourth embodiment of the present invention.
Figure 10 shows a state in which a ventilation grill is installed according to a modification of the fourth embodiment of the present invention.
Figure 11 shows an air conditioning system according to a fifth embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

In addition, in various embodiments, components having the same configuration will be representatively described in the first embodiment using the same symbols, and in other embodiments, only configurations different from the first embodiment will be described. do.

Please note that the drawings are schematic and not drawn to scale. The relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and are not limiting. And for identical structures, elements, or parts that appear in two or more drawings, the same reference numerals are used to indicate similar features.

The embodiments of the present invention specifically represent ideal embodiments of the present invention. As a result, various variations of the diagram are expected. Accordingly, the embodiment is not limited to the specific shape of the illustrated area and also includes changes in shape due to manufacturing, for example.

Additionally, all technical and scientific terms used in this specification, unless otherwise defined, have meanings commonly understood by those skilled in the art to which the present invention pertains. All terms used in this specification are selected for the purpose of more clearly explaining the present invention and are not selected to limit the scope of rights according to the present invention.

In addition, expressions such as 'comprising', 'comprising', 'having', etc. used in this specification imply the possibility of including other embodiments, unless otherwise stated in the phrase or sentence containing the expression. It should be understood as open-ended terms.

In addition, singular expressions described herein may include plural meanings unless otherwise specified, and this also applies to singular expressions described in the claims.

Additionally, expressions such as 'first' and 'second' used in this specification are used to distinguish a plurality of components from each other and do not limit the order or importance of the components.

Hereinafter, an air conditioning system 101 according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 4.

Figure 1 is a plan layout diagram showing an air conditioning system 101 according to a first embodiment of the present invention. And FIG. 2 is a cross-sectional view showing one of the plurality of rooms 10 in which the air conditioning system 101 is installed, and FIG. 3 is an enlarged view of portion A of FIG. 2. Figure 4 is an enlarged plan view showing the arrangement ecology of the ventilation grill 200 and the air supply diffuser 300 used in the air conditioning system 101.

For example, the air conditioning system 101 according to the first embodiment of the present invention can be used for cooling and heating in the indoor space of a building structure.

At this time, the indoor space of the building structure includes a plurality of rooms 10 and a corridor 15 connecting the plurality of rooms 10. In addition, the indoor space may further include a separately partitioned machine room 17 for installing an air conditioner 500, which will be described later.

As shown in FIG. 1, the air conditioning system 101 according to the first embodiment of the present invention includes a ventilation grill 200, an air supply diffuser 300, an air supply duct 630, a ventilation groove 29, and an air conditioner. Includes 500.

Additionally, the air conditioning system 101 according to the first embodiment of the present invention may further include a ventilation grill 200.

In addition, although not shown, the air conditioning system 101 may further include a ventilation device connected to the air supply duct 630 and the ventilation duct 620. Here, the ventilation device may include a heat exchanger. The heat exchanger improves energy use efficiency by exchanging heat between outside air supplied into the indoor space and indoor air discharged outdoors. Additionally, the ventilation device may further include a filter for filtering air introduced from the outside.

Additionally, the air conditioner 500 may incorporate the functions of the aforementioned ventilation device without installing a separate ventilation device.

The air conditioner 500 can supply cold air or warm air to the indoor space through the air supply diffuser 300, which will be described later. That is, the air conditioning system 101 can perform cooling and heating functions for the indoor space through the air conditioner 500.

As shown in Figure 2, the ventilation groove 29 is formed adjacent to the wall 30 of the building structure, so that the space between the slab 40 of the building structure and the ceiling panel 20 is used as an air supply diffuser to be described later. (300) communicates with the indoor space through which air is discharged. That is, the ventilation groove 29 is an interior space where the air supply diffuser 300 discharges air in the space between the slab 40 of the building structure and the ceiling panel 20 between the wall 30 and the air supply diffuser 300, which will be described later. It is formed to communicate with space. Here, the wall 30 may be an outer wall or an inner wall of a building structure. And when the wall 30 is an external wall, a window may be provided in the wall 30.

And in the first embodiment of the present invention, the ventilation grooves 29 may be formed adjacent to the wall 30 on the corridor 15 side for each of the plurality of rooms 10. At this time, the skylight panel 200 may be penetrated to form the ventilation groove 29, or the spaced space between the ceiling panel 200 and the wall 30 may become the ventilation groove 29.

Additionally, the ventilation groove 29 may be formed continuously and long along one side of the ceiling panel 20, as shown in FIG. 4. That is, the ventilation groove 29 may be formed long along one edge of the indoor space.

The ventilation grill 200 may be coupled to the ventilation groove 29 or disposed to be supported on the ventilation groove 29. Figure 3 exemplarily shows a state in which the ventilation grill 200 is coupled to the ventilation groove 29.

Meanwhile, in the first embodiment of the present invention, the ventilation grill 200 is not an absolutely necessary component and may be optionally omitted.

The air supply diffuser 300 is installed on the ceiling panel 20 adjacent to the wall 30 of the building structure and discharges air toward the indoor space in a direction opposite to the direction of the wall 30. And a ventilation groove 29 may be formed between the air supply diffuser 300 and the wall 30.

In the first embodiment of the present invention, the air supply diffuser 300 may be installed on the ceiling panel 20 so as to be adjacent to the hallway wall 30 for each of the plurality of rooms 10. And the air supply diffuser 300 discharges air toward the indoor space in the direction opposite to the direction of the corridor side wall 30, that is, the ventilation groove 29.

Specifically, as shown in FIG. 3, the air supply diffuser 300 may include a diffuser frame 320 and a wind direction control drum 310.

The lower part of the diffuser frame 320 is connected to the ceiling panel 20, and may have a slot or a square-shaped outlet 325 formed continuously along one side of the ceiling panel 20. For example, the discharge port 325 may be slot-shaped or elongated and rectangular. Additionally, a wind direction control drum 310, which will be described later, may be installed at the discharge port 325 of the diffuser frame 320. Additionally, the upper part of the diffuser frame 320 may be connected to an air supply duct 630, which will be described later.

Meanwhile, the upper part of the diffuser frame 320 may be coupled to the chamber 800, and an air supply duct 800 may be connected to the chamber 800. That is, the air conditioning system 101 may further include a duct 800 connected to the diffuser frame 320. In this case, the chamber 800 converts the flow of air induced through the air supply duct 630 to guide the air to the discharge port 325 of the diffuser frame 320. The chamber 800 may have a duct connector for connection to the air supply duct 630, and the upper part of the chamber 800 and the diffuser frame 320 can be connected by various coupling methods known to those skilled in the art, such as screw coupling. Can be separably combined.

Additionally, so that the diffuser frame 320 can be easily coupled or separated from the chamber 800 and the ceiling panel 20 of the building structure, the diffuser frame 320 may be separated into an upper frame and a lower frame.

The wind direction control drum 310 is rotatably inserted into the diffuser frame 320, and the wind direction of the air discharged from the discharge port 325 of the diffuser frame 320 can be adjusted depending on the rotation angle. In addition, a portion of the wind direction control drum 310 protrudes from the discharge port 325 of the diffuser frame 320 toward the indoor space, that is, in the downward direction, so that air can be discharged in a direction parallel to the ceiling panel 20. there is.

Specifically, the wind direction control drum 310 may include a drum body 315, a plurality of linear airflow outlets 311, and a plurality of linear airflow inlets 319.

The drum body 315 may have a length in a direction parallel to the discharge port 325 of the diffuser frame 320 and may include a hollow cylindrical shape continuously elongated along one side of the ceiling panel 20. At this time, the bottom surfaces of both sides of the drum body 315 may be in a closed shape.

As shown in FIG. 4, a plurality of linear airflow outlets 311 may be formed intermittently in one area of the side of the drum body 315 along the longitudinal direction of the drum body 315. At this time, the total area opened by the plurality of linear airflow outlets 311 in the drum body 315 and the gap between the plurality of intermittently formed linear airflow outlets 311 are connected to the air supply diffuser 300 through the air supply duct 630. It can be determined by the amount of air supplied and the area of the indoor space.

A plurality of linear airflow inlets 319 may be formed intermittently in parallel with the plurality of linear airflow outlets 311 in other areas of the side of the drum body 315 opposite to the plurality of linear airflow outlets 311. That is, the plurality of linear airflow inlets 319 may be formed to correspond to the plurality of linear airflow outlets 311.

Due to this structure, the air that moves along the air supply duct 630 and is guided to the discharge port 325 of the diffuser frame 320 flows into the linear airflow inlet 319 of the wind direction control drum 310 and then flows through the linear airflow outlet. As it is discharged to (311), it may be discharged into the indoor space. At this time, the air supply diffuser 300 can discharge air in various wind directions depending on the rotation angle of the wind direction control drum 310.

Specifically, the wind direction control drum 310 discharges the wind direction of the air discharged from the discharge port 325 of the diffuser frame 320 in a direction selected from downward, right, or left depending on the rotation angle, or in a direction selected from the direction of the diffuser frame 320. The discharge port 325 can be closed by blocking it.

In particular, the air supply diffuser 300 can move air discharged to the right or left according to the rotation angle of the wind direction control drum 310 along the ceiling panel 20 of the building structure using the Coanda effect.

For example, Figure 3 shows a state in which the wind direction control drum 310 discharges air to the right. As shown in FIG. 3, when it is desired to discharge air to the right through the air supply diffuser 300, the wind direction control drum 310 can be rotated so that the linear airflow outlet 311 faces to the right.

In particular, when the wind direction control drum 310 induces the discharge of air to the right to cause the Coanda effect, the left edge of the linear airflow outlet 311 in the longitudinal cross section of the drum body 315 is the drum body 315. It may protrude to the right by a preset discharge angle θ1 from the vertical reference line CL passing through the center of 315 . Here, the preset discharge angle θ1 may fall within the range of 3 degrees to 15 degrees.

Accordingly, the air discharged from the linear airflow outlet 311 moves slightly upward toward the ceiling panel 20 of the building structure and then moves along the ceiling panel 20 of the building structure due to the Coanda effect.

At this time, when the preset discharge angle (θ1) is less than 3 degrees, a portion of the air discharged from the air supply diffuser 300 does not obtain the Coanda effect and descends. As such, the Coanda effect is weakened and the air supply diffuser 300 The overall average reach distance of the discharged air becomes shorter.

Conversely, even when the preset discharge angle (θ1) exceeds 15 degrees, the air discharged from the air supply diffuser 300 hits the ceiling panel 20 of the building structure and the direction of the air flow changes, weakening the Coanda effect and causing the air supply diffuser ( In 300), the overall average reach distance of the discharged air becomes shorter.

That is, as in the first embodiment of the present invention, when the preset discharge angle θ1 falls within the range of 3 degrees to 15 degrees, the Coanda effect is maximized and the overall average reach distance of the air discharged from the air supply diffuser 300 It was confirmed through experiment that is the longest.

Additionally, the opening angle θ2 of the linear airflow outlet 311 in the longitudinal reference cross-section of the drum body 315 may fall within the range of 40 degrees to 60 degrees.

For example, when the opening angle θ2 of the linear airflow outlet 311 is smaller than 40 degrees, the maximum air volume that can be discharged by the air supply diffuser 300 is reduced, and the air generated from the wind direction control drum 310 is reduced. Resistance increases.

Conversely, if the opening angle θ2 of the linear airflow outlet 311 is greater than 60 degrees, the Coanda effect, in which the discharged air spreads and moves along the ceiling panel 20 of the building structure, may be weakened. That is, as the opening angle θ2 of the linear airflow outlet 311 becomes greater than 60 degrees, the reach distance of the air discharged from the air supply diffuser 300 may become shorter.

Additionally, the linear airflow inlet 319 may be formed at the same angle and size on the opposite side of the linear airflow outlet 311.

However, the first embodiment of the present invention is not limited to this, and the opening angle of the linear airflow inlet 319 may be set differently from that of the linear airflow outlet 311. In this case, the angle at which the linear airflow inlet 319 protrudes from the vertical reference line CL may also be different.

However, if the opening angle of the linear airflow inlet 319 is too small than the linear airflow outlet 311 located on the opposite side, air cannot flow smoothly into the linear airflow inlet 319, which may increase airflow resistance and noise. there is.

In addition, the wind direction control drum 310 is installed so that a portion of the wind direction control drum 310 protrudes from the discharge port 325 of the diffuser frame 320 toward the indoor space, that is, in the downward direction by a preset length, which effectively generates the Coanda effect and allows the user to This is to make it easier to manually adjust the rotation angle of the wind direction control drum 310.

For example, the preset length may be 1/4 of the diameter of the drum body 315 of the wind direction control drum 310. That is, if the diameter of the drum body 315 is 40 mm, the maximum length protruding from the discharge port 325 of the diffuser frame 320 may be 10 mm.

However, the first embodiment of the present invention is not limited to the above-mentioned, and the above-mentioned preset length is an example of a case where the wind direction control drum 310 induces the discharge of air to the right to cause the Coanda effect. In explanation, in the longitudinal reference cross-section of the drum body 315, the left edge of the linear airflow outlet 311 has a preset discharge angle θ1 protruding to the right from the vertical reference line CL passing through the center of the drum body 315. ) and can be set in various ways depending on the opening angle (θ2) of the linear airflow outlet 311.

However, if the preset length is too long, the wind direction control drum 310 may be exposed too much to the outside and may stand out, damaging the aesthetics. If the preset length is too short, the user may have to manually adjust the angle of the wind direction control drum 310. Not only does it become difficult to do, but it also becomes difficult to induce the Coanda effect.

In this way, by using the Coanda effect, the air discharged from the air supply diffuser 300 can be sent over a considerable distance. That is, one air supply diffuser 300 can cover a large area of the indoor space, and there is no need to install multiple air supply diffusers 300, so the slab 40 of the building structure is installed to connect to the air supply diffuser 300. The length of the air supply duct 630 constructed between and the ceiling panel 200 can be greatly reduced.

In addition, when it is desired to discharge air downward through the air supply diffuser 300, the rotation angle of the wind direction control drum 310 can be adjusted so that the linear airflow outlet 311 and the linear airflow inlet 319 are arranged in the vertical direction. there is. That is, the linear airflow outlet 311 and the linear airflow inlet 319 may be arranged along a vertical line passing through the rotation center of the drum body 315.

In addition, inside the drum body 315, there is an airflow guide wall 316 to suppress vortices from occurring in the process of moving the air flowing into the plurality of linear airflow inlets 319 to the plurality of linear airflow discharge ports 311. This can be formed.

Due to the structure of the wind direction control drum 310, not all of the air flowing into the linear airflow inlet 319 is discharged directly to the linear airflow outlet 311, and a swirling or vortex flow occurs inside the drum body 315, which has a hollow cylindrical shape. This may cause airflow resistance.

However, in the first embodiment of the present invention, the airflow guide wall 316 is installed inside the drum body 315 to direct air flowing into the linear airflow inlet 319 of the wind direction control drum 310 through the linear airflow outlet ( 311).

Accordingly, the air supply diffuser 300 discharges air in the horizontal direction through the wind direction control drum 310 and moves it far along the ceiling panel 20 of the building structure by the Coanda effect by the airflow guide wall 316. It is possible to effectively suppress airflow resistance from increasing inside the drum body 315 of the wind direction control drum 310.

Meanwhile, the rotation angle of the wind direction control drum 310 can be manually set by the user depending on the environmental conditions in which the air supply diffuser 300 is installed, and can also be adjusted by electrically rotating it using a drive motor (not shown).

For example, when a drive motor is used, the rotation angle of the wind direction control drum 310 can be automatically adjusted without the user having to manually adjust the rotation angle of the wind direction control drum 310.

Therefore, the drive motor can be very useful in situations where it is difficult for the user to manually adjust the rotation angle of the wind direction control drum 310 because the height of the ceiling panel 20 is high.

Additionally, when a drive motor is used, it becomes possible to repeatedly rotate the wind direction control drum 310 in both directions within a preset rotation angle range. That is, the air supply diffuser 300 can implement left and right continuous rotational spraying and dispensing using a drive motor. Here, the preset rotation angle range can be set in various ways depending on the structure in which the wind direction control drum 310 is installed and the usage conditions. For example, the preset rotation angle range may be set within a range in which the wind direction control drum 310 can discharge leftward and rightward discharge.

For example, the drive motor may be a step motor that can precisely control the rotation angle.

Additionally, although not shown, the operation of the driving motor may be controlled by a control device, and the user may transmit commands through a control panel or remote controller.

Meanwhile, Figure 5 shows a modification of the first embodiment of the present invention.

As shown in FIG. 5, the spaced space between the ceiling panel 200 and the wall 30, specifically, the spaced space between the air supply diffuser 300 and the wall 30 can be the ventilation groove 29. there is.

Additionally, one side of the ventilation grill 200 may be supported on the diffuser frame 320 of the air supply diffuser 300, and the other side of the ventilation grill 200 may be supported on the support 37 installed on the wall 30.

Additionally, although not shown, the ventilation grill 200 may be formed integrally with the diffuser frame 320 of the air supply diffuser 300.

The air supply duct 630 connects the air conditioner 500 and the air supply diffuser 300 installed in each of the plurality of rooms 10 through the corridor 15. That is, one side of the air supply duct 630 is connected to the air supply diffuser 300, and the other side of the air supply duct 630 is connected to the air conditioner 500. And the air supply duct 630 is installed in the space between the slab 40 and the ceiling panel 20 and is directly connected to the air supply diffuser 300.

In the first embodiment of the present invention, the air supply diffuser 630 is installed on the ceiling panel 20 so as to be adjacent to the wall 30 on the corridor 15 side of each room, so the ceiling panel 20 of each room 10 The size of the air supply duct 630 installed above can be minimized, and thus the overall size of the air supply duct 630 used in the air conditioning system 101 can be minimized.

The ventilation duct 620 connects the space between the air conditioner 500 and the ceiling panel 20 and the slab 40 for each of the plurality of rooms 10 through the corridor 15. And the ventilation duct 620 may also be installed in the space between the slab 40 and the ceiling panel 20.

In addition, a ventilation opening 621 is provided on one side of the ventilation duct 620, and the ventilation opening 621 of the ventilation duct 620 is also located in the space between the ceiling panel 20 and the slab 40 for each of the plurality of rooms 10. It is located. At this time, the ventilation opening 621 of the ventilation duct 620 may be installed adjacent to the wall 30 on the corridor 15 side. That is, the air supply duct 630 is directly connected to the air supply diffuser 300, but the ventilation duct 620 is not directly connected to the ventilation groove 29.

In this way, on one side of the ventilation duct 620, a ventilation opening 621 located in the space between the slab 40 and the ceiling panel 20 is provided for each of the plurality of rooms 10, and on the other side of the ventilation duct 620 Connected to the air conditioner (500).

Accordingly, the air that moves into the space between the ceiling panel 20 and the slab 40 through the ventilation groove 29 flows into the ventilation duct 620 through the ventilation hole 621 and then flows through the ventilation duct 620. It moves to the conditioner 500.

In addition, when the ventilation opening 621 of the ventilation duct 620 is installed adjacent to the wall 30 on the corridor 15 side, the size of the ventilation duct 620 installed above the ceiling panel 20 of each room 10 can be adjusted to It is possible to minimize the overall size of the ventilation duct 620 used in the air conditioning system 101.

Additionally, the air supply duct 630 and the ventilation duct 620 may be sound-absorbing ducts. By using a suction duct, noise generated from a blower that generates power to move air through the air supply duct 630 or ventilation duct 620 can be reduced. For example, the blower may be built into the air conditioner 500 or separately installed in the air supply duct 630 or ventilation duct 620.

In addition, in the first embodiment of the present invention, both the air supply diffuser 300 and the ventilation groove 29 are provided in the space between the wall 30 of the building structure and the beam 50 of the building structure closest to the wall 30. can be formed.

Accordingly, not only can the space required for installation of the air conditioning system 101 be minimized, but also the gap between the ceiling panel 20 and the slab 40 can be reduced, thereby increasing the height of the indoor space or reducing the floor height of the building structure. It can be lowered.

With this configuration, the air conditioning system 101 according to the first embodiment of the present invention can not only minimize the use of ducts compared to the size of the indoor space, but can also be installed so as not to be conspicuous in appearance in the indoor space.

Specifically, in the air conditioning system 101 according to the first embodiment of the present invention, when the air supply diffuser 300 discharges air in the horizontal direction opposite to the direction of the ventilation groove 29, the discharged air has the Coanda effect. It moves along the ceiling panel 20, then circulates along the wall dividing the indoor space and the floor of the indoor space, through the ventilation groove 29 formed adjacent to the air supply diffuser 300, and the ceiling panel 20 and the slab ( After moving to the space between 40), it may flow into the ventilation duct 620 through the ventilation hole 621.

In addition, the wind direction of the air discharged from the air supply diffuser 300 can be freely adjusted at the installation site, and depending on the selective wind direction adjustment of the wind direction control drum 310, the air discharged from the discharge port 325 of the diffuser frame 320 The Coanda effect allows air to travel distances along the ceiling panels 20 of the building structure.

In addition, the air supply diffuser 300, ventilation groove 29, and ventilation grill 200 are installed at the edge of the indoor space, so that they are not only less visible to occupants in the indoor space, but are also less visible to occupants in the indoor space compared to the installation space occupied by the air supply diffuser 300. It becomes possible to perform ventilation for a large area of the indoor area.

In addition, the air conditioning system 101 according to the first embodiment of the present invention can minimize the use of ducts compared to the size of the indoor space, eliminate noise and dead zones where air does not flow in the indoor space, and can eliminate noise and dead zones in the indoor space when cooling. The cold draft phenomenon can also be effectively suppressed by preventing cold wind from blowing directly toward people.

In particular, the air conditioning system 101 according to the first embodiment of the present invention can be useful in building structures, such as schools, where the space inside the ceiling panel 20 is narrow and there are restrictions on installing ducts due to the beam 50. there is.

Hereinafter, the air conditioning system 102 according to the second embodiment of the present invention will be described with reference to FIGS. 6 and 7.

As shown in FIG. 6, in the air conditioning system 102 according to the second embodiment of the present invention, the ceiling panel 20 is installed so that the air supply diffuser 300 is adjacent to the window side wall 30 in each of the plurality of rooms 10. ) can be installed. And the ventilation groove 29 may be formed between the air supply diffuser 300 and the window side wall 30.

The air supply duct 630 may be connected to the air supply diffuser 300 installed in each of the plurality of rooms 10 through the corridor 15. At this time, the air supply duct 630 may extend from the hallway side wall 30 toward the window side wall 30 for each of the plurality of rooms 10 to be connected to the air supply diffuser 300.

The ventilation duct 620 may be connected to the space between the ceiling panel 20 and the slab 40 for each of the plurality of rooms 10 through the corridor 15. At this time, the ventilation opening 621 provided in the ventilation duct 620 may be installed relatively adjacent to the corridor-side wall 30 in each of the plurality of rooms 10 through the corridor 15.

In Figure 7, the wind direction control drum 310 of the air supply diffuser 300 shows a state in which air is discharged to the left.

As shown in FIG. 7, when it is desired to discharge air to the left through the air supply diffuser 300, the wind direction control drum 310 can be rotated so that the linear airflow outlet 311 faces to the left.

In particular, when the wind direction control drum 310 induces the discharge of air to the left to cause the Coanda effect, the right edge of the linear airflow outlet 311 in the longitudinal cross-section of the drum body 315 is adjacent to the drum body 315. It may protrude to the left by a preset discharge angle θ1 from the vertical reference line CL passing through the center of 315 . Here, the preset discharge angle θ1 may fall within the range of 3 degrees to 15 degrees.

Accordingly, the air discharged from the linear airflow outlet 311 moves slightly upward toward the ceiling panel 20 of the building structure and moves along the ceiling panel 20 of the building structure.

In this way, the operating principle and effect of the wind direction control drum 310 discharging air to the left to cause the Coanda effect are different from those of the wind direction control drum 310 described in the first embodiment, except for the direction in which the air is discharged. This is completely the same as the operating principle and effect of causing the Coanda effect by discharging air in the right direction.

However, in the second embodiment of the present invention, the air moving into the space between the ceiling panel 20 and the slab 40 through the ventilation groove 29 formed adjacent to the window side wall 30 is shown in Figure 5. As shown, it may move in the space between the ceiling panel 20 and the slab 40 and flow into the ventilation opening 621 of the ventilation duct 620 installed relatively adjacent to the hallway-side wall 30.

According to the second embodiment of the present invention, the air supply diffuser 300 of the air conditioning system 102 uses the Coanda effect to direct air from the window side wall 30 along the ceiling panel 20 to the hallway side wall 30. It moves in this direction, and then the air circulates in the direction of moving along the hallway side wall 30 toward the floor and then along the floor toward the window side wall 30.

As described above, when air circulates, heating efficiency can be improved and heating costs can be reduced when the air conditioning system 102 operates in the winter heating mode.

For example, in the winter, the indoor space is usually cold in the space adjacent to the window 35 and warm inside, resulting in a large temperature difference even within the same room. In the case of extremely large building structures, intense heating must be provided in the space adjacent to the window 35 to maintain an appropriate temperature, but it is common for the inside space to be cooled because the temperature is too high.

However, according to the second embodiment of the present invention, when the air conditioning system 102 circulates the air in the indoor space, the air moving to the hallway wall 30 along the ceiling panel 20 circulates and circulates inside the indoor space. Since warm air is pushed from the floor toward the window, the indoor space can be heated to an appropriate temperature even if the air supply diffuser 300 discharges air at a relatively low temperature. In other words, since the internal air of the indoor space is moved from the inside toward the window 35 near the floor surface where occupants are mainly located, the temperature inside is lowered and the temperature on the window 35 side is efficiently increased to reduce the temperature difference in the indoor space. It is possible to reduce the energy required for heating.

In addition, as in the case of the second embodiment of the present invention, when the air supply diffuser 300 is installed adjacent to the window side wall 30, the air discharge direction of the air supply diffuser 300 is adjusted to discharge air downward. The diffuser 300 may perform a similar function as an air curtain to suppress cold or warm air flowing in from a window.

Meanwhile, in the second embodiment of the present invention, the ventilation grill 200 may be coupled to the ventilation groove 29 or disposed on the ventilation groove 29, or may be optionally omitted.

With this configuration, the air conditioning system 102 according to the second embodiment of the present invention can not only minimize the use of ducts compared to the size of the indoor space, but can also be installed so as not to be conspicuous in appearance in the indoor space. Energy use efficiency can be greatly improved.

Hereinafter, the air conditioning system 103 according to the third embodiment of the present invention will be described with reference to FIG. 8.

As shown in FIG. 8, in the air conditioning system 103 according to the third embodiment of the present invention, like the second embodiment described above, the air supply diffuser 300 and the ventilation groove 29 each have a plurality of rooms ( It can be arranged to be adjacent to the window side wall 30 every 10).

For example, a ventilation grill 200 may be coupled to the ventilation groove 29 of FIG. 8 or the ventilation grill 200 may be disposed on the ventilation groove 29. That is, the ventilation groove 29 and the ventilation grill 200 may be arranged as previously shown in FIG. 7.

Meanwhile, the ventilation grill 200 may be omitted as in the second embodiment.

In addition, as previously described in FIG. 1, the air supply duct 630 may be connected to the air supply diffuser 300 installed in each of the plurality of rooms 10 through the corridor 15. At this time, the air supply duct 630 may extend from the hallway side wall 30 toward the window side wall 30 for each of the plurality of rooms 10 to be connected to the air supply diffuser 300.

The ventilation duct 620 may be connected to the space between the ceiling panel 20 and the slab 40 for each of the plurality of rooms 10 through the corridor 15. At this time, the ventilation opening 621 provided in the ventilation duct 620 may be installed relatively adjacent to the corridor-side wall 30 in each of the plurality of rooms 10 through the corridor 15.

However, the air conditioning system 103 according to the third embodiment of the present invention is installed on the window side wall 30 and transports air in the direction of the ventilation groove 29, that is, the ventilation grill 200 ( 750) may further be included.

The ventilation auxiliary transfer fan 750 forcibly blows air adjacent to the window side wall 30 toward the ventilation groove 29, that is, toward the ventilation grill 200.

For example, in the winter, the air adjacent to the window 35 is cooled by the cold air flowing into the window 35, and since cold air is relatively difficult to rise upward, the air circulating in the indoor space flows into the ventilation groove 29. It may be difficult to move to.

Accordingly, in the third embodiment of the present invention, a ventilation auxiliary transfer fan 750 is installed under the window side wall 30, that is, under the ventilation groove 29, so that the air circulating in the indoor space is effectively ventilated through the ventilation groove 29. Helps you move to

With this configuration, the air conditioning system 103 according to the third embodiment of the present invention can not only minimize the use of ducts compared to the size of the indoor space, but can also be installed so as not to be conspicuous in appearance in the indoor space. Air can be circulated more effectively in indoor spaces.

Hereinafter, the air conditioning system 104 according to the fourth embodiment of the present invention will be described with reference to FIG. 9.

As shown in FIG. 9, in the air conditioning system 104 according to the fourth embodiment of the present invention, the air supply diffuser 300 and the ventilation groove 29 are installed on the window side wall 30 for each of the plurality of rooms 10. Can be placed adjacent to each other.

However, in the case of the fourth embodiment of the present invention, a curtain box 25 is formed in the ceiling panel 20 adjacent to the window side wall 30 for each of the plurality of rooms 10, and the ventilation groove 29 is a curtain box. It may be formed on one or more of the vertical and horizontal sides of (25).

Accordingly, in the second embodiment of the present invention, external exposure of the ventilation groove 29 in the indoor space can be minimized, and space utilization can be increased, reducing the horizontal area occupied by the air supply diffuser 300 and the ventilation groove 29. It can be minimized.

Figure 8 exemplarily shows a state in which the ventilation groove 29 is installed on both the vertical and horizontal sides of the curtain box 25. However, the ventilation groove 29 may be installed only on either the vertical side or the horizontal side. It may be possible.

Meanwhile, the arrangement of the air supply duct 630 and the ventilation duct 620 and the air circulation in the indoor space are the same as the second embodiment described above.

With this configuration, the air conditioning system 104 according to the fourth embodiment of the present invention can not only minimize the use of ducts compared to the size of the indoor space, but can also be installed to be more inconspicuous in appearance in the indoor space. .

In particular, the air conditioning system 104 according to the fourth embodiment of the present invention can hide the ventilation groove 29 out of sight.

Figure 10 shows a modification of the fourth embodiment of the present invention.

As shown in FIG. 10, a ventilation grill 200 may be installed in the ventilation groove 29 formed on one or more of the vertical and horizontal sides of the curtain box 25. At this time, the ventilation grill 200 may be coupled to the ventilation groove 29 or disposed on the ventilation groove 29.

Hereinafter, the air conditioning system 105 according to the fifth embodiment of the present invention will be described with reference to FIG. 11.

As shown in FIG. 11, when the area of the indoor space is so large that it is difficult to sufficiently ventilate only with the air supply diffuser 300 installed at one edge of the indoor space, air supply diffusers 300 are installed on both edges of the indoor space facing each other. ) and the ventilation grill (200) can each be installed as a pair.

Accordingly, the air conditioning system 105 can perform cooling or heating even in very large indoor spaces that are difficult to cover with the air supply diffuser 300 installed at one edge of the indoor space, even if the Coanda effect is used.

At this time, the air discharged from the air supply diffusers 300 installed at both edges of the indoor space moves along the ceiling panel 20, collides with each other, and heads downward, and moves along the floor of the indoor space to the edges on both sides of the indoor space. It moves to the ventilation duct 620 through the ventilation grills 200 installed in each.

Although embodiments of the present invention have been described above with reference to the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. will be.

Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later in the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

10: Thread of Vengeance
15: Hallway
17: Machine room
20: Ceiling panel
29: Ventilation groove
30: Wall
35: window
40: slab
50: Bo
101, 102, 103, 104, 105: Air conditioning system
200: ventilation grille
300: Supply air diffuser
310: Wind direction control drum
311: linear airflow outlet
319: linear airflow inlet
315: drum body
316: air flow guide wall
320: Diffuser frame
325: discharge port
620: ventilation duct
621: vent
630: Air supply duct
750: Ventilation auxiliary transfer fan
800: Chamber

Claims (17)

In an air conditioning system for cooling and heating in the indoor space of a building structure,
An air supply diffuser installed on a ceiling panel adjacent to the wall of a building structure and discharging air toward the indoor space in a direction opposite to the direction of the wall;
a ventilation groove formed between the air supply diffuser and the wall to communicate a space between a slab of a building structure and the ceiling panel with an indoor space through which the air supply diffuser discharges air;
An air supply duct on one side connected to the air supply diffuser;
a ventilation duct on one side of which is provided with a ventilation opening and is located between the slab and the ceiling panel; and
An air conditioner connected to the other side of the air supply duct and the other side of the ventilation duct
Includes,
The air supply diffuser,
a diffuser frame whose lower part is connected to the ceiling panel and has a slot or a square-shaped outlet continuously formed along one side of the ceiling panel; and
It is rotatably inserted into the interior of the diffuser frame, and the wind direction of the air discharged from the discharge port of the diffuser frame is adjusted according to the rotation angle, and a portion of the diffuser frame protrudes from the discharge port toward the indoor space to form the ceiling panel and the Wind direction control drum that can discharge air even in parallel directions
Including,
The wind direction control drum is,
a drum body in the shape of a hollow cylinder having a length in a direction parallel to the discharge port of the diffuser frame and continuously extending along one side of the ceiling panel;
a plurality of linear airflow outlets formed intermittently along the longitudinal direction of the drum body in one area of the side of the drum body; and
A plurality of linear airflow inlets intermittently formed parallel to the plurality of linear airflow outlets in other areas of the side of the drum body opposite to the linear airflow outlets.
Includes,
When the wind direction control drum induces the discharge of air to the right to cause the Coanda effect, the left edge of the linear airflow outlet in the longitudinal reference cross section of the drum body is a vertical reference line passing through the center of the drum body. It protrudes to the right by a preset discharge angle,
When the wind direction control drum induces the discharge of air to the left to cause the Coanda effect, the right edge of the linear airflow outlet in the longitudinal reference cross section of the drum body is a vertical reference line passing through the center of the drum body. An air conditioning system that protrudes to the left by a preset discharge angle. According to paragraph 1,
When the air supply diffuser discharges air in a horizontal direction opposite to the direction of the ventilation groove, the discharged air moves along the ceiling panel through the Coanda effect and then circulates along the wall dividing the indoor space and the floor of the indoor space. The air conditioning system moves to the space between the ceiling panel and the slab through the ventilation groove and then flows into the ventilation duct through the ventilation hole. According to paragraph 1,
An air conditioning system further comprising a ventilation grill coupled to the ventilation groove or disposed over the ventilation groove. According to paragraph 1,
The interior space of the architectural structure includes a plurality of rooms and a corridor connecting the plurality of rooms,
The air supply diffuser is installed on the ceiling panel adjacent to the hallway wall in each of the plurality of rooms,
The ventilation groove is formed between the air supply diffuser and the corridor side wall,
The air supply duct is connected to the air supply diffuser installed in each of the plurality of rooms through the corridor,
An air conditioning system wherein the ventilation port provided in the ventilation duct is installed in each of the plurality of rooms through the corridor. According to paragraph 1,
The interior space of the architectural structure includes a plurality of rooms and a corridor connecting the plurality of rooms,
The air supply diffuser is installed on the ceiling panel adjacent to a window side wall in each of the plurality of rooms,
The ventilation groove is formed between the air supply diffuser and the window side wall,
The air supply duct is connected to the air supply diffuser installed in each of the plurality of rooms through the corridor,
An air conditioning system wherein the ventilation port provided in the ventilation duct is installed in each of the plurality of rooms through the corridor. According to clause 5,
The air conditioning system further includes a ventilation auxiliary transport fan installed on the window side wall to transport air in the direction of the ventilation groove. According to clause 5,
A curtain box is formed on the ceiling panel adjacent to the window side wall in each of the plurality of rooms,
An air conditioning system wherein the ventilation groove is installed on at least one of the vertical and horizontal sides of the curtain box. According to paragraph 1,
The air conditioner is an air conditioning system installed in a separate machine room from the indoor space of a building structure. According to paragraph 1,
An air conditioning system wherein the ventilation groove is formed continuously and long along one side of the ceiling panel. delete According to paragraph 1,
Further comprising a ventilation grill installed in the ventilation groove,
One side of the ventilation grill is supported on the diffuser frame of the air supply diffuser,
An air conditioning system in which the other side of the ventilation grill is supported on a support installed on the wall. delete delete According to paragraph 1,
An air conditioning system in which the preset discharge angle is within the range of 3 degrees to 15 degrees. In an air conditioning system for cooling and heating in the indoor space of a building structure,
An air supply diffuser installed on a ceiling panel adjacent to the wall of a building structure and discharging air toward the indoor space in a direction opposite to the direction of the wall;
a ventilation groove formed between the air supply diffuser and the wall to communicate a space between a slab of a building structure and the ceiling panel with an indoor space through which the air supply diffuser discharges air;
An air supply duct on one side connected to the air supply diffuser;
a ventilation duct on one side of which is provided with a ventilation opening and is located between the slab and the ceiling panel; and
An air conditioner connected to the other side of the air supply duct and the other side of the ventilation duct
Includes,
The air supply diffuser,
a diffuser frame whose lower part is connected to the ceiling panel and has a slot or a square-shaped outlet continuously formed along one side of the ceiling panel; and
It is rotatably inserted into the interior of the diffuser frame, and the wind direction of the air discharged from the discharge port of the diffuser frame is adjusted according to the rotation angle, and a portion of the diffuser frame protrudes from the discharge port toward the indoor space to form the ceiling panel and the Wind direction control drum that can discharge air even in parallel directions
Including,
The wind direction control drum is,
a drum body in the shape of a hollow cylinder having a length in a direction parallel to the discharge port of the diffuser frame and continuously extending along one side of the ceiling panel;
a plurality of linear airflow outlets formed intermittently along the longitudinal direction of the drum body in one area of the side of the drum body; and
A plurality of linear airflow inlets intermittently formed parallel to the plurality of linear airflow outlets in other areas of the side of the drum body opposite to the linear airflow outlets.
Includes,
An air conditioning system wherein an opening angle of the linear airflow outlet in the longitudinal cross-section of the drum body falls within a range of 40 degrees to 60 degrees. In an air conditioning system for cooling and heating in the indoor space of a building structure,
An air supply diffuser installed on a ceiling panel adjacent to the wall of a building structure and discharging air toward the indoor space in a direction opposite to the direction of the wall;
a ventilation groove formed between the air supply diffuser and the wall to communicate a space between a slab of a building structure and the ceiling panel with an indoor space through which the air supply diffuser discharges air;
An air supply duct on one side connected to the air supply diffuser;
a ventilation duct on one side of which is provided with a ventilation opening and is located between the slab and the ceiling panel; and
An air conditioner connected to the other side of the air supply duct and the other side of the ventilation duct
Includes,
The air supply diffuser,
a diffuser frame whose lower part is connected to the ceiling panel and has a slot or a square-shaped outlet continuously formed along one side of the ceiling panel; and
It is rotatably inserted into the interior of the diffuser frame, and the wind direction of the air discharged from the discharge port of the diffuser frame is adjusted according to the rotation angle, and a portion of the diffuser frame protrudes from the discharge port toward the indoor space to form the ceiling panel and the Wind direction control drum that can discharge air even in parallel directions
Including,
The wind direction control drum is,
a drum body in the shape of a hollow cylinder having a length in a direction parallel to the discharge port of the diffuser frame and continuously extending along one side of the ceiling panel;
a plurality of linear airflow outlets formed intermittently along the longitudinal direction of the drum body in one area of the side of the drum body; and
A plurality of linear airflow inlets intermittently formed parallel to the plurality of linear airflow outlets in other areas of the side of the drum body opposite to the linear airflow outlets.
Includes,
An air conditioning system in which an airflow guide wall is formed inside the drum body to suppress the generation of vortices while the air flowing into the plurality of linear airflow inlets moves to the plurality of linear airflow discharge ports. According to paragraph 1,
The wind direction control drum is capable of discharging the wind direction of air discharged from the discharge port of the diffuser frame in a direction selected from downward, rightward, or leftward depending on the rotation angle, or closing the discharge port of the diffuser frame. An air conditioning system.

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