JP7591704B2 - Air Conditioning System - Google Patents

Description

The present invention relates to an air conditioning system that conditions multiple spaces.

Traditionally, homes have been air-conditioned using central air conditioners. Furthermore, with the growing demand for energy-saving homes and stricter regulations, it is expected that the number of highly insulated and airtight homes will increase, and there is a demand for air-conditioning systems that are suited to these characteristics.

One such type of air conditioning system is a whole-building air conditioning system, which conditions the air transported from multiple spaces (rooms) to an air-conditioning room to a predetermined temperature and humidity level, and then transports the air to each of the multiple spaces (rooms) so that the air temperature and humidity in the multiple spaces become the target temperature and humidity (see, for example, Patent Document 1).

JP 2020-63899 A

In conventional whole-building air-conditioning systems, multiple fans installed in an air-conditioned room transport air from the air-conditioned room to multiple spaces. For this reason, in order to continuously transport humidified air according to the balance of the air volumes of the multiple fans, it was necessary to humidify the entire air in the air-conditioned room. However, there is a limit to the humidifying capacity of the humidifier, and if the amount of air transported (supplied) to the multiple spaces increases further, there is a high possibility that the humidifier will not be able to keep up with humidifying the entire air in the air-conditioned room. In other words, the humidifier will be able to humidify only a portion of the air in the air-conditioned room. As a result, there is a concern that some of the air humidified by the humidifier will be unevenly supplied to a specific fan located near the humidifier.

The present invention has been made to solve the above problems, and provides an air conditioning system that can supply air humidified by a humidifier to each of a number of blowers according to the balance of the airflow between the blowers.

To achieve this objective, the air conditioning system of the present invention comprises an air conditioning unit configured to be able to introduce air from the outside, an air conditioner installed in the air conditioning unit and adjusting the temperature of the air in the air conditioning unit, a humidifier installed in the air conditioning unit and humidifying the air whose temperature has been adjusted by the air conditioner, and a first blower and a second blower that transport the air in the air conditioning unit to a plurality of conditioned spaces independent of the air conditioning unit. The humidifier is characterized by having a first outlet that blows the humidified air towards the first blower, and a second outlet that blows the humidified air towards the second blower.

The present invention provides an air conditioning system that can supply air humidified by a humidifier to each of a number of blowers according to the air volume balance of the blowers.

FIG. 1 is a schematic connection diagram of an air conditioning system according to a first embodiment of the present invention. FIG. 2 is a schematic front view of an air conditioning unit that constitutes the air conditioning system. FIG. 3 is a schematic cross-sectional view of a humidifier constituting an air conditioning system. FIG. 4 is a schematic top view of a humidifier in an air conditioning unit. FIG. 5 is a schematic side view showing the air flow inside the air conditioning unit. FIG. 6 is a schematic front view showing the flow of air from the humidifier to the blower.

The air conditioning system according to the present invention includes an air conditioning unit configured to be able to introduce air from the outside, an air conditioner installed in the air conditioning unit and adjusting the temperature of the air in the air conditioning unit, a humidifier installed in the air conditioning unit and humidifying the air adjusted in temperature by the air conditioner, and a first blower and a second blower that transport the air in the air conditioning unit to a plurality of conditioned spaces independent of the air conditioning unit. The humidifier has a first outlet that blows the humidified air towards the first blower, and a second outlet that blows the humidified air towards the second blower.

With this configuration, even when the humidifier humidifies part of the air in the air conditioning unit, the air humidified by the humidifier can be reliably supplied to each of the blowers (first blower, second blower) regardless of the relative positions of the humidifier and the blowers. In other words, an air conditioning system can be created that can supply air humidified by the humidifier to each of the blowers according to the air volume balance of the multiple blowers.

In the air conditioning system according to the present invention, it is preferable that the first air outlet is arranged to face the first air inlet of the first blower, and the second air outlet is arranged to face the second air inlet of the second blower. This ensures that air humidified by the humidifier is supplied to the air inlets of each blower.

In addition, the air conditioning system according to the present invention preferably includes a partition plate that separates a first flow path, through which air blown out from the first outlet reaches the first inlet, from a second flow path, through which air blown out from the second outlet reaches the second inlet. This makes it possible to prevent the humidified air supplied to the second blower from being sucked into the first blower due to the difference in air volume (pressure difference) when the air volume balance between the first blower and the second blower is significantly different, for example, when the air volume of the first blower is greater than the air volume of the second blower. As a result, it is possible to prevent the air humidified by the humidifier from being unevenly supplied to a specific blower depending on the air volume balance of the multiple blowers.

In addition, in the air conditioning system according to the present invention, it is preferable that the first blower has a third suction port, which draws in air whose temperature has been adjusted by the air conditioner, on the surface opposite to the surface where the first suction port faces the first outlet, and the second blower has a fourth suction port, which draws in air whose temperature has been adjusted by the air conditioner, on the surface opposite to the surface where the second suction port faces the second outlet. This makes it possible to transport a portion of the air in the air conditioning unit that has been humidified by the humidifier from the first suction port and second suction port of the blower (first blower, second blower), while transporting the remaining portion of the air in the air conditioning unit from the third suction port and fourth suction port of the blower without passing through the humidifier.

The following describes an embodiment of the present invention with reference to the drawings. Note that the following embodiment is an example of the present invention, and does not limit the technical scope of the present invention. Also, each figure described in the embodiment is a schematic diagram, and the ratio of the size and thickness of each component in each figure does not necessarily reflect the actual dimensional ratio.

(Embodiment 1)
First, an overview of an air conditioning system 101 according to a first embodiment of the present invention will be described with reference to Fig. 1. Fig. 1 is a configuration diagram of the air conditioning system 101 according to the first embodiment of the present invention.

The air conditioning system 101 is a system for conditioning multiple spaces in a building with a single air conditioner. As shown in FIG. 1, the air conditioning system 101 is configured with an air conditioning unit 1, multiple ducts 11 (ducts 11a, 11b), multiple branch chambers 12 (branch chambers 12a, 12b), a damper 13 (dampers 13a-13d), an indoor temperature and humidity sensor 14 (indoor temperature and humidity sensors 14a-14d), an air supply port 15 (air supply ports 15a-15d), and a controller 30. The air conditioning system 101 conditions the conditioned space 16 (described below) using air whose temperature and humidity have been adjusted in the air conditioning unit 1.

Specifically, the air conditioning system 101 is installed in a house 100, which is an example of a building. The house 100 has air-conditioned spaces 16 (air-conditioned spaces 16a-16d) corresponding to rooms such as a living room, bedroom, dining room, study, etc., shared spaces 17 (shared spaces 17a, 17b) corresponding to a hallway, staircase, atrium, etc., and a dedicated installation space 20 in which the air-conditioning unit 1 is installed independently of the air-conditioned spaces 16 and the shared spaces 17.

The conditioned space 16 is a space that is the target of air conditioning in the air conditioning system 101. The conditioned space 16 includes conditioned spaces 16a and 16b located on the second floor of the house 100, and conditioned spaces 16c and 16d located on the first floor of the house 100. Air that has been temperature and humidity adjusted is supplied to the conditioned spaces 16a to 16d from the air conditioning unit 1, which will be described later.

The common space 17 is a space that is not subject to air conditioning by the air conditioning system 101. The common space 17 includes a common space 17a located on the second floor of the house 100, and a common space 17b located on the first floor of the house 100. The common spaces 17a and 17b are connected to each other via a staircase or the like (not shown). Note that, like the conditioned space 16, air whose temperature and humidity has been adjusted may be supplied to the common space 17 from the air conditioning unit 1 described below.

The dedicated installation space 20 is a space in which the air conditioning unit 1 is stored and installed. The dedicated installation space 20 is also provided with a door (not shown), which faces, for example, the common space 17. This allows easy maintenance of the air conditioning unit 1 in the dedicated installation space 20.

The air conditioning unit 1 is installed in a dedicated installation space 20, and is a unit that draws in air from within the house 100, adjusts the temperature (cools or heats) and humidifies the air, and then sends it out. Details will be described later.

The duct 11 is provided in the attic 18 or the space within the ceiling 19, and is a member that communicates and connects the air conditioning unit 1 and the conditioned space 16. The inner or outer wall surface of the duct 11 is insulated with glass wool, for example. The duct 11 is provided with a branch chamber 12 on the air conditioning unit 1 side of the duct 11, and a damper 13 and an air intake 15 on the air conditioned space 16 side of the duct 11. More specifically, the duct 11 includes a duct 11a provided in the attic 18 on the second floor and a duct 11b provided in the ceiling 19 on the first floor. The duct 11a is provided with a branch chamber 12a on the air conditioning unit 1 side of the duct 11a, and dampers 13a, 13b and air intakes 15a, 15b on the air conditioned space 16 side of the duct 11a. In addition, a branch chamber 12b is provided in the duct 11b on the air conditioning unit 1 side, and dampers 13c, 13d and air intakes 15c, 15d are provided on the duct 11b on the conditioned space 16 side.

The branch chamber 12 is installed on the air conditioning unit 1 side of the duct 11, and is a chamber that branches the air (temperature and humidity regulated air) sent out from the air conditioning unit 1 to multiple conditioned spaces 16. The branch chamber 12 includes a branch chamber 12a provided in the duct 11a and a branch chamber 12b provided in the duct 11b. The branch chamber 12a branches the air sent out from the air conditioning unit 1 into two systems, the conditioned space 16a and the conditioned space 16b. The branch chamber 12b branches the air sent out from the air conditioning unit 1 into two systems, the conditioned space 16c and the conditioned space 16d.

The damper 13 is installed on the conditioned space 16 side of the duct 11, and is a member that adjusts the amount of air passing through the air supply port 15 by changing the opening degree from fully open to fully closed by a motor or the like. The damper 13 is connected to the controller 30 wirelessly or by wire so as to be able to communicate, and the opening degree of the damper 13 is controlled by a control signal from the controller 30. More specifically, the damper 13 includes a damper 13a provided in one duct 11a and a damper 13b provided in the other duct 11a of the two systems of ducts 11a branched by the branch chamber 12a, and a damper 13c provided in one duct 11b and a damper 13d provided in the other duct 11b of the two systems of ducts 11b branched by the branch chamber 12b. Damper 13a is installed on the conditioned space 16a side of one duct 11a and adjusts the volume of air passing through air supply port 15a. Damper 13b is installed on the conditioned space 16b side of the other duct 11a and adjusts the volume of air passing through air supply port 15b. Damper 13c is installed on the conditioned space 16c side of one duct 11b and adjusts the volume of air passing through air supply port 15c. Damper 13d is installed on the conditioned space 16d side of the other duct 11b and adjusts the volume of air passing through air supply port 15d.

The air intake 15 is installed on the floor, wall, or ceiling of the air-conditioned space 16, and is an opening that blows air (conditioned air) from the air-conditioning unit 1 into the air-conditioned space 16 through the duct 11. More specifically, the air intake 15 includes an air intake 15a installed in the air-conditioned space 16a, an air intake 15b installed in the air-conditioned space 16b, an air intake 15c installed in the air-conditioned space 16c, and an air intake 15d installed in the air-conditioned space 16d. The air intake 15a and the air intake 15b blow air from the air-conditioning unit 1 into the air-conditioned space 16a and the air-conditioned space 16b, respectively, through the duct 11a. The air intake 15c and the air intake 15d blow air from the air-conditioning unit 1 into the air-conditioned space 16c and the air-conditioned space 16d, respectively, through the duct 11b.

In addition, the indoor temperature and humidity sensor 14 is installed in the air-conditioned space 16 and detects the temperature (indoor temperature) and humidity (indoor humidity) of the air in the air-conditioned space 16. The indoor temperature and humidity sensor 14 is connected to the controller 30 wirelessly or wired so as to be able to communicate with the controller 30, and outputs information related to the detected indoor temperature and indoor humidity to the controller 30. More specifically, the indoor temperature and humidity sensor 14 includes an indoor temperature and humidity sensor 14a installed in the air-conditioned space 16a, an indoor temperature and humidity sensor 14b installed in the air-conditioned space 16b, an indoor temperature and humidity sensor 14c installed in the air-conditioned space 16c, and an indoor temperature and humidity sensor 14d installed in the air-conditioned space 16d. The indoor temperature and humidity sensor 14a detects the indoor temperature of the air-conditioned space 16a and outputs it to the controller 30. The indoor temperature and humidity sensor 14b detects the indoor temperature and indoor humidity of the air-conditioned space 16b and outputs it to the controller 30. The indoor temperature and humidity sensor 14c detects the indoor temperature and indoor humidity of the air-conditioned space 16c and outputs them to the controller 30. The indoor temperature and humidity sensor 14d detects the indoor temperature and indoor humidity of the air-conditioned space 16d and outputs them to the controller 30.

The controller 30 is installed on a wall in a room where the main part of daily life is spent, such as a living room (for example, the conditioned space 16b), and controls the operation of the air conditioning unit 1 and the opening degree of the damper 13 as control of the air conditioning system 101 based on the setting information input and set by the user. Details will be described later.

Next, the configuration of the air conditioning unit 1 will be described with reference to FIG. 2. FIG. 2 is a schematic front view of the air conditioning unit 1 of the air conditioning system 101.

As described above, the air conditioning unit 1 is installed in the dedicated installation space 20, and is a unit that draws in air from within the house 100, adjusts the temperature (cools or heats up) and humidifies the air, and then sends it out. In other words, the air conditioning unit 1 adjusts the temperature and humidity of the air that it draws in.

Specifically, as shown in FIG. 2, the air conditioning unit 1 has a unit body 2, an air conditioner 3, a blower 4, an air conditioning intake 5, an air conditioner installation space 6, a blower installation space 7, a humidifier installation space 52, an air conditioning outlet 8 (see FIG. 5), a filter 9, an intake temperature and humidity sensor 40 (see FIG. 5), a humidifier 51, and a partition plate 80.

The unit body 2 is a housing that forms the outer shell of the air conditioning unit 1. The unit body 2 has an air conditioning intake port 5 formed on the top side and an air conditioning outlet port 8 (see Figure 5) formed on the back side. The unit body 2 has an air conditioner 3, a blower 4, a humidifier 51, and a filter 9 installed inside.

The air conditioner 3 is installed in the air conditioner installation space 6 located on the upper side of the unit body 2, and is a device that conditions the air drawn into it through the air conditioning inlet 5. The air conditioner 3 is connected to the controller 30 wirelessly or via wire so that it can communicate with the controller 30, and the air conditioning operation (heating operation or cooling operation) is controlled by a control signal from the controller 30. During heating operation, the air conditioner 3 heats the drawn air and blows it out, and during cooling operation, it cools the drawn air and blows it out.

The blower 4 is installed in the blower installation space 7 located in the middle of the unit body 2, and is a device for blowing air in the unit body 2 from the air conditioning outlet 8. The blower 4 has two air intakes 41 and 42 at the top and bottom of the housing, and can blow air from both the air conditioner installation space 6 at the top of the blower installation space 7 and the humidifier installation space 52 at the bottom of the blower installation space 7. In other words, the blower 4 sucks in conditioned air containing air humidified by the humidifier 51 from the air intake 41, and sucks in conditioned air whose temperature has been adjusted by the air conditioner 3 from the air intake 42. The blower 4 is also connected to the controller 30 wirelessly or by wire so as to be able to communicate, and the blowing operation is controlled by a control signal from the controller 30. Then, the operation of the blower 4 forms a series of air flows by the air conditioning unit 1. The detailed air flow path of the air conditioning unit 1 will be described later.

More specifically, the blowers 4 include a first blower 4a that blows air to the conditioned space 16 on the second floor (conditioned spaces 16a and 16b) and a second blower 4b that blows air to the conditioned space 16 on the first floor (conditioned spaces 16c and 16d). The first blower 4a and the second blower 4b have the same configuration and the same functions.

The first blower 4a has a first air intake 41a on the bottom surface of the housing (the surface facing the humidifier installation space 52) and a third air intake 42a on the top surface of the housing (the surface facing the air conditioner installation space 6). The first air intake 41a is arranged to face the first humidifier outlet 62a of the humidifier 51 described later. In other words, the first blower 4a has a third air intake 42a that draws in air whose temperature has been adjusted by the air conditioner 3 on the surface opposite to the surface on which the first air intake 41a faces the first humidifier outlet 62a. The first air intake 41a corresponds to the "first intake" in the claims, and the third air intake 42a corresponds to the "third intake" in the claims.

The second blower 4b has a second air intake 41b on the bottom surface of the housing (the surface facing the humidifier installation space 52) and a fourth air intake 42b on the top surface of the housing (the surface facing the air conditioner installation space 6). The second air intake 41b is arranged to face the second humidifier outlet 62b of the humidifier 51 described later. In other words, the second blower 4b has a fourth air intake 42b that draws in air whose temperature has been adjusted by the air conditioner 3 on the surface opposite to the surface on which the second air intake 41b faces the second humidifier outlet 62b. The second air intake 41b corresponds to the "second intake" in the claims, and the fourth air intake 42b corresponds to the "fourth intake" in the claims.

The air conditioning intake 5 is a rectangular opening provided on the top surface of the unit body 2. The rectangular width of the air conditioning intake 5 is equal to the width of the unit body 2. The air conditioning intake 5 draws in air from the dedicated installation space 20 when the blower 4 operates. Note that the air conditioning intake 5 is not limited to being provided on the top surface, but may be provided near the air intake of the air conditioner 3.

The air conditioner installation space 6 is a space in the upper part of the interior of the unit body 2 where the air conditioner 3 is installed.

The blower installation space 7 is a space in the middle of the interior of the unit body 2 where the blower 4 is installed.

The humidifier installation space 52 is a space in the lower part of the interior of the unit body 2 where the humidifier 51 is installed.

As shown in FIG. 5 described later, the air conditioning outlet 8 is provided on the rear side of the unit body 2 and is an opening through which air (conditioned air) whose temperature and humidity has been adjusted inside the unit body 2 is blown out. The air conditioning outlet 8 is connected in communication with the duct 11. More specifically, the air conditioning outlet 8 includes a first air conditioning outlet 8a connected in communication with the duct 11a and a second air conditioning outlet 8b connected in communication with the duct 11b. The first air conditioning outlet 8a opens toward the top of the unit body 2, and the second air conditioning outlet 8b opens toward the bottom of the unit body 2.

The filter 9 is installed between the air conditioner installation space 6 and the blower installation space 7, and is a component that removes fine particles such as dirt and dust from the air passing through, and purifies the air supplied from the air conditioning outlet 8 through the duct 11 to the conditioned space 16. The filter 9 is, for example, an air filter such as a HEPA (High Efficiency Particulate Air) filter. The filter 9 is a HEPA filter of a specified thickness arranged flat inside the unit body 2.

The humidifier 51 is located below the blower 4 inside the unit body 2, and when the humidity of the air in the conditioned space 16 (indoor humidity) is lower than the target humidity (indoor target humidity) set by the user, it humidifies the air in the unit body 2 so that the humidity becomes the target humidity. The humidity values handled here are each indicated as relative humidity, but may be handled as absolute humidity by a specified conversion process. In this case, it is preferable to handle the entire handling in the air conditioning unit 1, including the humidity of the conditioned space 16, as absolute humidity. The humidifier 51 is connected to the controller 30 wirelessly or by wire so as to be able to communicate, and the humidification operation is controlled by a control signal from the controller 30.

The partition plate 80 is provided in the humidifier installation space 52 above the humidifier 51, extending vertically from the upper surface of the humidifier 51 to the lower surface of the blower 4. The partition plate 80 separates a first flow path through which the humidified air blown out from the first humidification outlet 62a of the humidifier 51 reaches the first air intake port 41a of the first blower 4a, from a second flow path through which the humidified air blown out from the second humidification outlet 62b of the humidifier 51 reaches the second air intake port 41b of the second blower 4b.
In other words, the partition plate 80 is positioned in the humidifier installation space 52 so as to selectively separate the space through which air (air Q3 described later) blown out from the humidifier outlet 62 of the humidifier 51 flows (see Figures 3 and 4).

Next, the configuration of the humidifier 51 will be described with reference to Figures 2 to 4. Figure 3 is a schematic cross-sectional view of the humidifier 51 that constitutes the air conditioning system 101. Figure 4 is a schematic top view of the humidifier 51 in the air conditioning unit 1. Note that in Figure 4, the positions of the first air intake 41a of the first blower 4a, the second air intake 41b of the second blower 4b, and the partition plate 80 are indicated by dashed lines.

The humidifier 51 is located downstream of the air conditioner 3 in the unit body 2, and is a device for humidifying the air in the unit body 2 by centrifugal water crushing. As shown in FIG. 3, the humidifier 51 is equipped with a humidifier intake 61 that draws in air in the unit body 2, a humidifier outlet 62 that blows humidified air into the unit body 2, an air passage provided between the humidifier intake 61 and the humidifier outlet 62, and a liquid atomization chamber 63 provided in the air passage.

The humidifier intake 61 is provided on the top surface of the housing that constitutes the outer frame of the humidifier 51. As shown in FIG. 4, the humidifier intake 61 is configured with four fan-shaped openings in the central portion of the humidifier 51. The humidifier intake 61 draws air (air whose temperature has been adjusted by the air conditioner 3) from within the humidifier installation space 52 into the device.

As shown in FIG. 4, the humidification outlet 62 is configured with a pair of openings arranged on either side of the humidification inlet 61. The humidification outlet 62 blows out air humidified within the device into the humidification device installation space 52. In other words, the humidification outlet 62 blows out air humidified within the device toward the blower 4.

More specifically, as shown in Figures 2 and 4, the humidification outlet 62 includes a first humidification outlet 62a corresponding to the first blower 4a and a second humidification outlet 62b corresponding to the second blower 4b.

The first humidification outlet 62a is disposed opposite the first air intake 41a of the first blower 4a, and blows out air humidified within the device toward the first air intake 41a. At this time, the first humidification outlet 62a and the first air intake 41a are disposed close to each other so that the humidified air blown out from the first humidification outlet 62a is drawn into the first air intake 41a via the shortest path. The first humidification outlet 62a corresponds to the "first outlet" in the claims.

The second humidification outlet 62b is disposed opposite the second air intake 41b of the second blower 4b, and blows out air humidified within the device toward the second air intake 41b. At this time, the second humidification outlet 62b and the second air intake 41b are disposed close to each other so that the humidified air blown out from the second humidification outlet 62b is drawn into the second air intake 41b via the shortest path. The second humidification outlet 62b corresponds to the "second outlet" in the claims.

The liquid atomization chamber 63 is the main part of the humidification device 51, where water is atomized using a centrifugal water crushing method.

Specifically, as shown in FIG. 3, the humidifier 51 includes a liquid atomization chamber 63, a rotary motor 64, a rotary shaft 65 rotated by the rotary motor 64, a centrifugal fan 66, a cylindrical water lift pipe 67, a water storage section 70, a first eliminator 71, and a second eliminator 72.

The lift pipe 67 is fixed to the rotating shaft 65 inside the liquid atomization chamber 63, and while rotating in accordance with the rotation of the rotating shaft 65, it pumps up water from a circular lift port provided vertically downward. More specifically, the lift pipe 67 has an inverted cone-shaped hollow structure, and has a circular lift port provided vertically downward, and a rotating shaft 65 arranged vertically is fixed above the lift pipe 67 and at the center of the top surface of the inverted cone. The rotating shaft 65 is connected to a rotating motor 64 located vertically above the liquid atomization chamber 63, so that the rotational motion of the rotating motor 64 is transmitted to the lift pipe 67 through the rotating shaft 65, causing the lift pipe 67 to rotate.

The rise pipe 67 is provided with a number of rotating plates 68 formed on the top surface side of the inverted cone shape so as to protrude outward from the outer surface of the rise pipe 67. The rotating plates 68 are formed so as to protrude outward from the outer surface of the rise pipe 67 with a certain distance between adjacent rotating plates 68 in the axial direction of the rotating shaft 65. Since the rotating plates 68 rotate together with the rise pipe 67, it is preferable that they have a horizontal disk shape coaxial with the rotating shaft 65. The number of rotating plates 68 is set appropriately according to the target performance or the dimensions of the rise pipe 67.

The wall of the water rise pipe 67 is provided with a number of openings 69 that penetrate the wall of the water rise pipe 67. Each of the openings 69 is provided at a position that communicates the inside of the water rise pipe 67 with the upper surface of a rotating plate 68 that is formed to protrude outward from the outer surface of the water rise pipe 67.

The centrifugal fan 66 is disposed vertically above the water lift pipe 67 and serves to draw air into the device from the unit body 2. The centrifugal fan 66 is fixed to the rotating shaft 65, just like the water lift pipe 67, and rotates in accordance with the rotation of the rotating shaft 65 to introduce air into the liquid atomization chamber 63.

The water storage section 70 is located vertically below the lift pipe 67 and stores the water that the lift pipe 67 lifts from the lift port. The depth of the water storage section 70 is designed so that a portion of the lower part of the lift pipe 67, for example a length of about one-third to one-hundredth of the cone height of the lift pipe 67, is submerged. This depth can be designed according to the required amount of water to be lifted. The bottom surface of the water storage section 70 is formed in a cone shape facing the lift port. Water is supplied to the water storage section 70 by a water supply section (not shown).

The first eliminator 71 is a porous body through which air can flow, and is provided to the side (outer periphery in the centrifugal direction) of the liquid atomization chamber 63, and is arranged so that air can flow in the centrifugal direction. In the first eliminator 71, the water droplets discharged from the opening 69 of the water lift pipe 67 collide with the first eliminator 71, atomizing the water droplets and collecting the water droplets contained in the air passing through the liquid atomization chamber 63. As a result, the air flowing through the humidifier 51 contains only vaporized water.

The second eliminator 72 is provided downstream of the first eliminator 71 and is arranged so that air can flow vertically upward. The first eliminator 71 is also a porous body through which air can flow, and the air that has passed through the first eliminator 71 collides with it, capturing water droplets from the water contained in the air passing through the first eliminator 71. In this way, the fine water droplets are captured doubly by the two eliminators, making it possible to capture large water droplets with greater precision.

Next, the operating principle of humidification (water atomization) in the humidifier 51 will be explained with reference to Figure 3. In Figure 3, the flow of air and the flow of water within the device are indicated by arrows.

First, when the operation of the humidifier 51 is started, the rotary motor 64 rotates the rotary shaft 65 at the first rotation speed R1, and the centrifugal fan 66 starts sucking air from the unit body 2 through the humidification inlet 61. Then, the water pumping pipe 67 rotates in accordance with the rotation of the rotary shaft 65 at the first rotation speed R1. Then, as shown by the water flow indicated by the dashed arrow, the centrifugal force generated by the rotation causes the water stored in the water storage section 70 to be pumped up by the water pumping pipe 67. Here, the first rotation speed R1 of the rotary motor 11 (water pumping pipe 67) is set between 2000 rpm and 5000 rpm, for example, depending on the air blowing volume and the amount of humidification of the air. Since the water pumping pipe 67 has an inverted cone-shaped hollow structure, the water pumped up by the rotation is pumped up along the inner wall of the water pumping pipe 67 to the upper part. The pumped water is then released in the centrifugal direction from the opening 69 of the pumping pipe 67 along the rotating plate 68, and is scattered as water droplets.

The water droplets scattered from the rotating plate 68 fly through the space surrounded by the first eliminator 71 (liquid atomization chamber 63), collide with the first eliminator 71, and are atomized. Meanwhile, the air passing through the liquid atomization chamber 63 moves to the outer periphery of the first eliminator 71, as shown by the air flow indicated by the solid arrow, while containing the water crushed (atomized) by the first eliminator 71. Then, as the air flows through the air passage from the first eliminator 71 to the second eliminator 72, a vortex of the airflow is generated, and the water and air are mixed. Then, the air containing the water passes through the second eliminator 72. This allows the humidifier 51 to humidify the air sucked in through the humidification inlet 61 and blow out the humidified air from the humidification outlet 62.

The liquid to be atomized may be something other than water, such as hypochlorous acid water, which has bactericidal or deodorizing properties.

Next, the air conditioning operation of the air conditioning system 101 will be described with reference to Figures 1 and 2.

As described above, in the air conditioning system 101, the controller 30 controls the operation of the air conditioning unit 1 and the opening degree of the damper 13.

The controller 30 is a control unit that controls the entire air conditioning system 101. The controller 30 has a computer system having a processor and a memory. The processor executes a program stored in the memory, causing the computer system to function as a control unit. Here, the program executed by the processor is pre-recorded in the memory of the computer system, but it may be provided by recording it on a non-transitory recording medium such as a memory card, or it may be provided via a telecommunications line such as the Internet.

The controller 30 is connected to the air conditioner 3, the blower 4, the damper 13, the indoor temperature and humidity sensor 14, and the humidifier 51 so that they can communicate wirelessly or by wire. The controller 30 controls the air conditioner 3 (as an air conditioner), the air volume of the blower 4, the opening degree of the damper 13, and the humidification amount of the humidifier 51 according to the indoor temperature and indoor humidity of each air-conditioned space 16 acquired by the indoor temperature and humidity sensor 14, and the target temperature (indoor target temperature) and target humidity (indoor target humidity) set for each air-conditioned space 16a to 16d. The air volume of the blower 4 is controlled individually for each blower.

As a result, air whose temperature and humidity have been adjusted by the air conditioning unit 1 is transported to each conditioned space 16 at the air volume set by each blower 4 (first blower 4a, second blower 4b) and each damper 13 (dampers 13a to 13d). Therefore, the indoor temperature and indoor humidity of each conditioned space 16 are controlled to be the target temperature (indoor target temperature) and target humidity (indoor target humidity).

More specifically, when a user executes an air conditioning process, the controller 30 acquires information regarding the indoor target temperature and humidity (indoor target temperature and indoor target humidity) set by the user. Here, the indoor target temperature and humidity is the temperature and humidity that the user feels comfortable with, and is the temperature and humidity common to all conditioned spaces 16.

When the indoor target temperature and humidity are acquired, the controller 30 acquires information regarding the indoor temperature and humidity from the indoor temperature and humidity sensors 14 installed in each conditioned space 16. Next, the controller 30 calculates the temperature difference and humidity difference from the target from the acquired information regarding the indoor target temperature and humidity and the information regarding the indoor temperature and humidity.

The controller 30 then determines the air-conditioning room target temperature and humidity (air-conditioning room target temperature and air-conditioning room target humidity) for the air in the air-conditioning unit 1 based on the calculated temperature difference and humidity difference. Here, the air-conditioning room target temperature is set to a temperature higher than the indoor target temperature, and the air-conditioning room target humidity is set to a humidity higher than the indoor target humidity.

Then, the controller 30 determines the control conditions for the air conditioner 3, the blower 4, the damper 13, and the humidifier 51 based on the identified target temperature and humidity of the air-conditioned room, and executes each of them.

Specifically, the controller 30 starts the operation of the air conditioner 3 based on the control conditions of the air conditioner 3, and executes temperature control so that the temperature of the air in the air conditioning unit 1 becomes the air-conditioned room target temperature. Also, the controller 30 starts the rotation operation of the rotary motor 64 based on the control conditions of the humidifier 51, and rotates it at the first rotation speed R1 (2000 rpm to 5000 rpm) so that the humidity of the air in the air conditioning unit 1 becomes the air-conditioned room target humidity. Furthermore, the controller 30 changes the air volume of the blower 4 and the opening degree of the damper 13 to the set air volume and opening degree, respectively, based on the control conditions of the blower 4 and the damper 13. The opening degree of the damper 13 is set according to the temperature difference between the air temperature in the conditioned space 16 and the indoor target temperature, and is set to be widened if the temperature difference is large, and set to be narrowed if the temperature difference is small.

Then, during air conditioning operation, if a predetermined time T has elapsed since the above-mentioned control conditions were set, the controller 30 acquires new information regarding the indoor temperature and humidity from the indoor temperature and humidity sensors 14 installed in each conditioned space 16. On the other hand, if the predetermined time T has not elapsed, the controller 30 continues air conditioning operation under the same control conditions. Here, the predetermined time T is the cycle time for acquiring the indoor temperature and humidity in the indoor temperature and humidity sensor 14, and is set to, for example, 5 minutes.

In the air conditioning system 101, air conditioning operations are performed for the conditioned space 16 in the manner described above.

Next, the air flow in the air conditioning unit 1 will be described with reference to Figures 5 and 6. Figure 5 is a schematic side view showing the air flow in the air conditioning unit 1. Figure 6 is a schematic front view showing the air flow from the humidifier 51 to the blower 4.

As shown in FIG. 5, the air conditioning unit 1 takes in air Q1 from the conditioned space 16 through the air conditioning intake 5. The taken-in air Q1 is then sucked into the air conditioner 3, where it is temperature-regulated (cooled or heated) and blown out as air Q2 into the air conditioner installation space 6. The blown-out air Q2 flows through the filter 9 into the blower installation space 7.

The air Q2 that flows into the blower installation space 7 is divided into air Q2a that is sucked directly into the air intake 42 on the upper surface of the blower 4, and air Q2b that flows around to the humidifier installation space 52 and is sucked in from the air intake 41 on the lower surface of the blower. Here, the air Q2b flows through a certain space provided between the blower 4 and the front panel 10 side of the air conditioning unit 1 and flows into the humidifier installation space 52. Then, most of the air Q2b that flows into the humidifier installation space 52 flows through the humidifier 51 and is humidified. After that, the air that has been humidified through the humidifier 51 mixes with the air Q2b that has flowed into the humidifier installation space 52 that has not passed through the humidifier 51, and becomes air Q3, which is sucked in from the air intake 41 on the lower surface of the blower 4. The volume of air flowing through the humidifier 51 varies depending on the volume of air from the blower 4.

Then, the air Q2a sucked in from the air intake 42 and the air Q3 sucked in from the air intake 41 are mixed inside the blower 4 and sent out as air Q4 from the air conditioning outlet 8. The sent out air Q4 is then branched and supplied to each of the conditioned spaces 16 via the duct 11 (see FIG. 1).

More specifically, the blowers 4 blow air Q4a from the first air conditioning outlet 8a via the first blower 4a, and blow air Q4b from the second air conditioning outlet 8b via the second blower 4b, with the respective blowing volumes controlled by the controller 30.

As shown in FIG. 6, the first blower 4a draws in air Q2a from the third blower suction port 42a and draws in air Q3a from the first blower suction port 41a. The first blower 4a then mixes the air Q2a drawn in from the third blower suction port 42a with the air Q3a drawn in from the first blower suction port 41a, and sends it out as air Q4a from the first air conditioning outlet 8a (see FIG. 5). The sent-out air Q4a is then blown out through the duct 11a into the conditioned space 16a and the conditioned space 16b, respectively.

Meanwhile, the second blower 4b draws in air Q2a from the fourth blower suction port 42b and draws in air Q3b from the second blower suction port 41b. The second blower 4b then mixes the air Q2a drawn in from the fourth blower suction port 42b with the air Q3b drawn in from the second blower suction port 41b, and sends it out as air Q4b from the second air conditioning outlet 8b (see FIG. 5). The sent-out air Q4b is then blown out through the duct 11b into the conditioned space 16c and the conditioned space 16d, respectively.

As described above, the partition plate 80 separates the first flow path, through which the humidified air blown out from the first humidifying outlet 62a of the humidifier 51 reaches the first air intake 41a of the first blower 4a, from the second flow path, through which the humidified air blown out from the second humidifying outlet 62b of the humidifier 51 reaches the second air intake 41b of the second blower 4b. Therefore, the partition plate 80 has the role of preventing the air Q3a and the air Q3b from mixing in the humidifier installation space 52 when the air volumes between the first blower 4a and the second blower 4b are different, that is, when the difference in air volume between the blowers is large.

Here, in the case where the partition plate 80 is not provided, when the air volumes between the first blower 4a and the second blower 4b are equal, the air Q3a blown out from the first humidifying outlet 62a and the air Q3b blown out from the second humidifying outlet 62b are sucked into the air intake port 41 of the corresponding blower 4 directly above. However, when the air volumes between the first blower 4a and the second blower 4b are different, for example, when the air volume of the first blower 4a is greater than the air volume of the second blower 4b, due to the difference in air volume (pressure difference), not only the air Q3a blown out from the first humidifying outlet 62a, but also a part of the air Q3b blown out from the second humidifying outlet 62b is sucked into the first blower 4a. In other words, the air humidified by the humidifier 51 is sucked in unevenly into the first blower 4a. In addition, when the air Q3b passes directly above the humidification intake port 61 while being drawn into the first blower 4a, some of the air Q3b may be drawn into the humidification device 51 through the humidification intake port 61, causing a short circuit.

On the other hand, when the partition plate 80 is provided, even if the air volume of the first blower 4a is greater than the air volume of the second blower 4b, the partition plate 80 can prevent the air supplied to the second blower 4b from being sucked into the first blower 4a due to the difference in air volume (pressure difference). In other words, the partition plate 80 allows the first blower 4a and the second blower 4b to selectively suck in the air blown out from their respective humidification outlets 62, preventing a portion of that air from being sucked into the adjacent blower 4 and preventing a short circuit from occurring in the process.

As described above, the air conditioning system 101 according to the first embodiment provides the following advantages:

(1) The air conditioning system 101 includes an air conditioning unit 1 configured to be able to introduce air from the outside, an air conditioner 3 installed in the air conditioning unit 1 and adjusting the temperature of the air in the air conditioning unit 1, a humidifier 51 installed in the air conditioning unit 1 and humidifying the air adjusted in temperature by the air conditioner 3, and a first blower 4a and a second blower 4b that transport the air in the air conditioning unit 1 to a plurality of conditioned spaces 16 (conditioned spaces 16a to 16d) independent of the air conditioning unit 1. The humidifier 51 is configured to have a first humidification outlet 62a that blows humidified air Q3a toward the first blower 4a, and a second humidification outlet 62b that blows humidified air Q3b toward the second blower 4b.

As a result, even when the humidifier 51 humidifies a portion of the air in the air conditioning unit 1, the air Q3 humidified by the humidifier 51 can be reliably supplied to each of the blowers 4 (first blower 4a, second blower 4b) regardless of the relative positions of the humidifier 51 and the blowers 4. In other words, the air conditioning system 101 can supply the air Q3 humidified by the humidifier 51 to each of the blowers 4 according to the air volume balance of the multiple blowers 4.

(2) In the air conditioning system 101, the first humidifying outlet 62a is positioned to face the first air intake 41a of the first blower 4a, and the second humidifying outlet 62b is positioned to face the second air intake 41b of the second blower 4b. This ensures that the air Q3 humidified by the humidifier 51 can be reliably supplied to the air intake 41 of each blower 4.

(3) The air conditioning system 101 is provided with a partition plate 80 that separates the first flow path, through which the air Q3a blown out from the first humidifying outlet 62a reaches the first air intake 41a, from the second flow path, through which the air Q3b blown out from the second humidifying outlet 62b reaches the second air intake 41b. As a result, when the air volume balance between the first blower 4a and the second blower 4b is significantly different, for example, when the air volume of the first blower 4a is larger than the air volume of the second blower 4b, the partition plate 80 can prevent the humidified air (air Q3b) supplied to the second blower 4b from being sucked into the first blower 4a due to the air volume difference (pressure difference). As a result, it is possible to prevent the air Q3 humidified by the humidifying device 51 from being biasedly supplied to a specific blower 4 according to the air volume balance of the multiple blowers 4.

(4) In the air conditioning system 101, the first blower 4a has a third blower suction port 42a, which draws in air Q2a whose temperature has been adjusted by the air conditioner 3, on the side opposite to the side where the first blower suction port 41a faces the first humidifying outlet 62a, and the second blower 4b has a fourth blower suction port 42b, which draws in air Q2a whose temperature has been adjusted by the air conditioner 3, on the side opposite to the side where the second blower suction port 41b faces the second humidifying outlet 62b. This allows a portion of the air in the air conditioning unit 1 that has been humidified by the humidifier 51 to be transported from the first air inlet 41a and second air inlet 41b of the blower 4 (first blower 4a, second blower 4b), while the remaining portion of the air in the air conditioning unit 1 can be transported from the third air inlet 42a and fourth air inlet 42b of the blower 4 without passing through the humidifier 51.

The present invention has been described above based on an embodiment. This embodiment is merely an example, and it will be understood by those skilled in the art that various modifications are possible in the combination of each component or each processing process, and that such modifications are also within the scope of the present invention.

In the air conditioning system 101 according to the first embodiment, two blowers 4 (first blower 4a, second blower 4b) have been described, but this is not limited to the above. For example, three or more blowers may be used, and a humidification outlet of the humidifier may be provided corresponding to the air intake of each blower. In this way, the same effect can be obtained.

The air conditioning system of the present invention is useful as it can supply air humidified by a humidifier to each of a number of blowers according to the balance of the airflow between the blowers.

REFERENCE SIGNS LIST 1 air conditioning unit 2 unit body 3 air conditioner 4 blower 4a first blower 4b second blower 5 air conditioning intake 6 air conditioner installation space 7 blower installation space 8 air conditioning outlet 8a first air conditioning outlet 8b second air conditioning outlet 9 filter 10 front panel 11, 11a, 11b duct 12, 12a, 12b branch chamber 13, 13a to 13d damper 14, 14a to 14d indoor temperature and humidity sensor 15, 15a to 15d air intake 16, 16a to 16d conditioned space 17, 17a, 17b shared space 18 attic 19 ceiling 20 dedicated installation space 30 controller 41 air intake 41a First air intake 41b Second air intake 42 Air intake 42a Third air intake 42b Fourth air intake 51 Humidifier 52 Humidifier installation space 61 Humidification intake 62 Humidification outlet 62a First humidification outlet 62b Second humidification outlet 63 Liquid atomization chamber 64 Rotary motor 65 Rotating shaft 66 Centrifugal fan 67 Water lift pipe 68 Rotating plate 69 Opening 70 Water storage section 71 First eliminator 72 Second eliminator 80 Partition plate 100 House 101 Air conditioning system Q1 Air Q2, Q2a, Q2b Air Q3, Q3a, Q3b Air Q4, Q4a, Q4b Air T Predetermined time

Claims (2)

An air conditioning unit configured to be able to introduce air from the outside;
an air conditioner that is installed in the air conditioning unit and adjusts the temperature of air in the air conditioning unit;
a humidifier that is installed in the air conditioning unit and that humidifies the air whose temperature has been adjusted by the air conditioner;
A first fan and a second fan that transport air from the air conditioning unit to a plurality of conditioned spaces independent of the air conditioning unit;
Equipped with
The humidifier includes a first outlet for blowing humidified air toward the first blower and a second outlet for blowing humidified air toward the second blower,
The first air outlet is disposed to face a first air inlet of the first blower,
the second air outlet is disposed to face the second air inlet of the second blower,
the first blower has a third suction port, which draws in air whose temperature has been adjusted by the air conditioner, on a surface opposite to a surface on which the first suction port faces the first air outlet,
An air conditioning system characterized in that the second blower has a fourth intake port on the side opposite to the side where the second intake port faces the second outlet port, which draws in air whose temperature has been adjusted by the air conditioner . The air conditioning system according to claim 1, further comprising a partition plate separating a first flow path through which air blown out from the first air outlet reaches the first air inlet, and a second flow path through which air blown out from the second air outlet reaches the second air inlet.

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