JP2012057880A - Air-conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique for reducing an inter-room temperature difference even under an influence of external environment conditions such as hours of sunlight.SOLUTION: An air-conditioning system S1 includes an air-conditioner chamber 1 in which an air-conditioner 2 is disposed, external air intakes 311 and 400 which are formed on the air-conditioner chamber 1 and at least take in air outside the air-conditioner chamber 1, the air-conditioner 2 which is disposed in the air-conditioner chamber 1 and air-conditions the air-conditioner chamber 1 with external air taken in from the external air intakes 311 and 400, a plurality of ducts 3 each of which has one opening arranged on the side of the air-conditioner chamber 1 and the other opening guided to each room of a house, and blowers 4 each of which is disposed on each of the ducts 3. In the air-conditioning system S1, the air-conditioner chamber 1 has a mixing unit 33 which mixes the external air with outflow air flowing out of the air-conditioner 2 before both the external air and the outflow air are sent to one opening of each duct 3.

Description

  The present invention relates to an air conditioning system.

  One of the air-conditioning systems is a residential duct-type whole building air-conditioning system (hereinafter referred to as a central air-conditioning system) that is often used in highly airtight and highly insulated houses. However, as the air conditioning area increases and the operation time increases, energy consumption tends to increase as compared to an air conditioner (hereinafter, air conditioner) system that is an individual air conditioner. Particularly in a house having a plurality of rooms, the solar radiation time varies depending on the direction of each room. Therefore, a difference occurs in the room temperature of each room.

On the other hand, in the conventional central air-conditioning systems, there is one installed blower and a constant air volume. For this reason, it is difficult to control the air volume in each room, and as a result, there is a risk of causing a decrease in comfort due to unnecessary air conditioning, overheating, and overcooling.
Therefore, the current central air conditioning system does not make full use of the excellent thermal performance of highly airtight and highly insulated houses.

Therefore, an air conditioner installed in the air conditioner room, and a plurality of ducts installed such that one port is installed on the air conditioner side in the air conditioner room and the other port is led to each room in the house. For example, Patent Document 1 discloses a technique including a blower that is provided at the other opening of each duct and blows air from an air conditioner toward each room.
With the technique disclosed in Patent Document 1, the rotational speed of the blower installed for each duct can be changed. Thereby, the air volume for each room can be adjusted by adjusting the air volume blown into each room.

  Air conditioning is an abbreviation for the term air conditioning, and refers to equipment that uses a machine to adjust the air condition for people or objects inside the building. Air has three elements: temperature, humidity, and pressure, and usually contains impure gas and dust. Equipment that keeps the temperature and humidity of air moderate and removes impurities is called air conditioning equipment.

Japanese Patent Laid-Open No. 10-325565

“Air-conditioning and sanitary engineering society”, “Mechanism of comfortable thermal environment”, pages 148-149 and Figs.

  However, the conventional technology does not take the following considerations. That is, the air conditioner room does not necessarily have a uniform temperature, and there are high-temperature parts and low-temperature parts, and there may be a temperature difference in each part.

  For this reason, due to the temperature difference, that is, in the case of a duct that sucks in air from a hot part in the air conditioner room, the temperature of the air guided to the duct is high, so The temperature rises.

  On the contrary, in the case of a duct that sucks air from a low-temperature part in the air conditioner room, the temperature of the air guided to the duct is lower, so the temperature of the room to which the air is supplied becomes lower. Therefore, there is a problem that a difference in air-conditioning temperature is generated for each room, and a temperature difference (hereinafter, a temperature difference between rooms) is still generated for each room. For this reason, the comfort of each room and the house as a whole is hindered, and the energy consumption is also high.

  The present invention has been made in consideration of the above-described technical background, and a problem to be solved is to provide a technique capable of reducing the temperature difference between the rooms as compared with the conventional art.

In order to solve the above technical problem, the present invention has the following configuration.
That is, the air conditioning system of the present invention includes an air conditioner room in which an air conditioner is installed, an external air intake port that is formed in the air conditioner room and takes in external air that is at least outside the air conditioner room, and an air conditioner room. And an air conditioner that air-conditions the air conditioner room with external air taken in from the external air intake port, one of the ports is installed on the air conditioner room side, and the other port is in each room of the house An air conditioning system including a plurality of guided ducts and a blower provided in each of the plurality of ducts. The air conditioner room has a mixing unit that mixes the external air and the outflow air before the outflow air flowing out of the external air and the air conditioner is sent to one of the ports of the duct. .

  According to the air conditioning system of the present invention, the outside air directly introduced into the air conditioner room from the external air intake and the air flowing out from the air conditioner are mixed in the air conditioner room, and then directed to one of the ducts. It is aired. Therefore, the outside air temperature, the air at a temperature close to the outside air temperature (for example, the temperature of the air in the attic room when the air conditioner room is installed in the attic room) and the air at the temperature air-conditioned by the air conditioner are mixed. The temperature of the entire air conditioner room becomes almost uniform.

  Therefore, according to the air conditioning system of the present invention configured as described above, air of substantially uniform temperature is sent to each room via a plurality of ducts connecting the air-conditioned air chamber and each room. For this reason, the temperature difference between rooms can be decreased. Therefore, it can be said that it is an energy-saving air blowing system.

  As described above, according to the present invention, it is possible to provide a residential environment that does not have an extreme temperature difference for each room even under the influence of sunshine hours and other external environments.

Sectional drawing of the high airtightness and high heat insulation house to which the central air-conditioning system of Example 1 of this invention was applied 1 is a perspective view of FIG. The perspective view of the air-conditioning air chamber which concerns on Example 1. 3 is a longitudinal sectional view Viewed from the direction of arrow V in FIG. Viewed from the direction of arrow VI in FIG. Viewed from the direction of arrow VII in FIG. VIII-VIII sectional view of FIG. The perspective view of the air-conditioning air chamber which concerns on Example 2. 9 is a longitudinal sectional view Viewed from the direction of arrow XI in FIG. Viewed from the direction of arrow XII in FIG. XIII-XIII sectional view of FIG. XIV-XIV cross-sectional view of Fig. 11 Vertical sectional view of an air-conditioned air chamber according to Example 3 XVI-XVI sectional view of FIG. XVII-XVII sectional view of FIG. XVIII-XVIII sectional view of FIG. XIX-XIX sectional view of FIG. Temperature-time diagram of each room before the present invention is applied Temperature-time diagram of each room after the present invention is applied Comparative table for explaining the effect of the present invention

Hereinafter, modes for carrying out the present invention (hereinafter referred to as embodiments) will be exemplarily described based on examples. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention unless otherwise specified.
A preferred embodiment of an air conditioning system of the present invention will be described with reference to the drawings.

Example 1
A first embodiment will be described with reference to FIGS.
FIG. 1 shows a highly airtight and highly insulated house (hereinafter, house) to which the central air conditioning system S1 according to the present invention is applied.
High airtightness is to prevent drafts from entering the house, and high heat insulation is to prevent the warm air from escaping in the winter from the outer walls, roofs, windows, etc. that are in contact with the outside of the house. In summer, keep heat out. Therefore, highly airtight and highly insulated houses are filled with minute gaps in order to improve airtightness. Moreover, in order to improve heat insulation, the heat insulating material with high heat insulation performance is used, and a sash containing a double layer glass is used for the window.

(Central air conditioning system)
The central air-conditioning system (hereinafter referred to as air-conditioning system) S1 is for taking advantage of the excellent thermal performance of such a house (see FIGS. 1 and 2).

The following elements are included as important elements for that purpose.
That is, as can be seen from FIGS. 1 to 3, the air conditioning system S <b> 1 sends the air conditioner room 1 installed in the attic, the air conditioner 2 installed in the air conditioner room 1, and the outside air OA to the air conditioner room 1. An air supply duct 31, an attic air inlet 400 as an external air inlet for taking in air outside the air conditioner room 1 (attic air) into the air conditioner room 1, and outside air OA flowing toward the air conditioner room 1, The air flowing out from the air conditioner 2 (hereinafter referred to as air conditioner air) is mixed in the air conditioner room 1 so that the air temperature in the air conditioner room 1 is made uniform, and the mixing part 33 makes the temperature uniform. A plurality of air supply ducts 3 for guiding the air to each room of the house, an air supply fan 4 provided in each air supply duct 3 in the air conditioner room 1, and an exhaust for exhausting indoor air to the outdoors A duct 32.

(Air conditioner room 1)
The air conditioner room 1 is made of high airtightness and high heat insulation like a house. Thereby, the cold air and warm air which flowed out from the blower outlet of the air conditioner 2 become difficult to leak out of the air conditioner room 1. Further, the air conditioner room 1 has an outside air introduction port 311 into which one port of the air supply duct 31 is fitted, a gallery 15 as a ventilation port, and an inspection port 17 (see FIGS. 2, 3 and 5). Is provided.

(Outside air inlet 311)
The outside air introduction port 311 sends outside air, for example, outdoor air, through the air supply duct 31 to the air conditioner room 1.
It is an opening for taking in. A filter (not shown) for removing dust in the atmosphere is fitted in the opening surface. For this reason, outside air flows in into air-conditioner room 1 via a filter.

(Gallery 15)
The gallery 15 is a door with blades attached in parallel, and is provided in the air conditioner room 1 as shown in FIG. The gallery 15 communicates with a passage provided in the house for returning the air once out of the air conditioner room 1 from the air conditioner room 1 to the air conditioner room 1 via the house through the air supply duct 3. This passage is denoted by reference numeral 47 and is called a communication passage. When the louver 15 is connected to the communication passage 47, the supply air SA that has flowed out of the air conditioner room 1 flows into the residential room 42 of the house. Thereafter, the air in the living room is introduced into the hall 46 of the house and returns to the air conditioner room 1 via the communication path 47 connected to the gallery 15.

(Inspection port 17)
As shown in FIGS. 2, 3, and 5, the inspection port 17 is a door through which an inspector enters and leaves the air conditioner room 1 for maintenance and inspection of the air conditioner 2 and other devices installed in the air conditioner room 1. It is.
In Example 1, the inspection port 17 is formed in the one side wall 111 (refer FIG. 2) of the air-conditioner room 1, and the drooping wall 6 (refer FIG. 5).

(Air conditioner 2)
As shown in FIGS. 1 to 5 and 8, the air conditioner 2 is installed on one side wall 111 of the air conditioner room 1. The air conditioner 2 performs air conditioning of the air conditioner room 1 with the outside air flowing into the air conditioner room 1 from the air supply duct 31. The air conditioner 2 is sufficient if it is commercially available for home use that also has an air conditioning function. The air conditioner 2 is configured to circulate chlorofluorocarbon gas between the indoor unit 21 installed inside the air conditioner room 1, the outdoor unit 22 installed outside the air conditioner room 1, and the indoor unit 21 and the outdoor unit 22. A piping pipe (not shown) to be piped.

(Air supply duct 31)
As shown in FIG. 1, an air supply duct 31 is provided near the attic in FIG.
The other side of the air supply duct 31 is attached to an outside air intake port 10 formed on the outer wall of the house, as shown in FIG. The air duct 31 has a deep hood 121 as an outside air introduction part, a filter unit 13 for removing dust in the atmosphere, and heat loss generated during cooling and heating from the other port toward the one port. In order to suppress, heat exchange air units 14 for recovering thermal energy are provided in order.

(Attic air inlet 400)
As shown in FIGS. 1 to 3 (particularly FIG. 3), an attic air inlet 400 is provided at the top of the air conditioner 2.

  The attic air inlet 400 is formed in an upper part of the one side wall 111 of the air conditioner room 1 near the ceiling. The attic air inlet 400 is a large rectangular hole, and the attic air is sucked into the air conditioner room 1 from here. Therefore, the width of the attic air inlet 400 is a dimension that extends from the end to the 2/3 position in the longitudinal direction of the side wall 111. However, the length of the side wall may be full.

  Further, the vertical width is approximately 1/3 of the ceiling height of the air conditioner room 1. In the air conditioner room 1, an inspection port 17 is formed on the right side toward the attic air suction port 40.

And dust usually exists on the back of the ceiling. Therefore, it is necessary to remove the dust so as not to be taken into the air conditioner room 1. Therefore, the entire surface of the attic air inlet 400 is covered with a dust removal filter 401 that removes dust.
The attic air inlet 400 and the outside air inlet 311 are referred to as an external air inlet for taking in air outside the air conditioner room.

  As shown in FIG. 3, in the side wall 111 where the attic air inlet 400 is formed, the air conditioner 2 is installed at a central portion in the longitudinal direction almost directly below the attic air inlet 400. The capacity of the air conditioner 2 (hereinafter referred to as air conditioner capacity) is determined by calculating the air conditioning load. In addition, the air conditioner capacity depends largely on the structure and construction of the house, and equipment selection is based on experience based on actual results.

  For example, in a normal house (about 140 m 2) in the heat insulation section 4 area, one air conditioner capacity (equivalent to 5 kw) may be installed. However, two or more units may be installed depending on the shape of the house and the way of living. When arranging a plurality of air conditioners, it is preferable that the air conditioners are arranged in series along the longitudinal direction almost directly below the attic air inlet 400.

(Mixing unit 33)
As shown in FIGS. 3 to 5, 7, and 8, the mixing unit 33 is one room of a separation room defined by hanging the hanging wall 6 on the ceiling surface of the air conditioner room 1. As can be seen from FIGS. 3 and 4, the hanging wall 6 is located between the air conditioner 2 and the blower 4. An outside air inlet 311 for taking in outside air via the air supply duct 31 is located in the mixing unit 33 (see FIGS. 1 to 3).

  The outside air inlet 311 may be provided beside the air conditioner 2 on the side wall 111 where the air conditioner 2 is installed. The outside air inlet 311 may be installed above the air conditioner. The room on the opposite side of the mixing unit 33 with the drooping wall 6 as a boundary is a room for dispersing the air in the air conditioner room in the living room of the house by the supply air blower 4 and is therefore referred to as a dispersion room. The dispersion chamber is indicated by 100.

(Hanging wall 6)
The drooping wall 6 shown in FIGS. 3 and 4 is configured so that the outside air taken in from the outside air inlet 311, the attic air taken in from the attic air inlet 400 and the air conditioner air are sent toward the air supply duct 3. It is a wall installed to prevent the air from moving and mix. Since the mixing portion is formed by the drooping wall 6, the dripping wall 6 is referred to as a mixing portion forming member.

The drooping wall 6 is also an defining plate that divides the air conditioner room 1 into two parts by dividing the internal space of the air conditioner room 1.
Furthermore, when the hanging wall 6 is suspended in the air conditioner room 1, the dimension is such that a ventilation space S that is a narrow path of about 30 to 50 cm can be formed between the hanging wall 6 and the floor surface 16 of the air conditioner room 1. Has been.

In the air conditioner room 1, the air conditioner 2 is disposed in one space with the hanging wall 6 as a boundary, and the attic air inlet 400 is formed on the one wall surface 111 of the air conditioner room 1 as described above. Is done. In the room on the other side of the hanging wall 6, the air supply blower 4 is arranged.
In addition, the inspection port 17 is also formed in the hanging wall 6 so as to face the inspection port 17 formed in the one wall surface 111 of the air conditioner room 1.

(Air supply fan 4)
As shown in FIGS. 3 and 4, the air supply fan 4 is attached to an air supply fan attachment wall 44 that is suspended from the ceiling surface so as to be parallel to the drooping wall 6. The supply fan mounting wall 44 has a lattice shape. In this embodiment, the supply air blower 4 is attached to the supply air blower mounting wall 44 in two separate upper and lower stages, with a total of 12 single-stage 6 units. Of the air supply fan mounting wall 44, the side opposite to the side where the hanging wall 6 is provided is secured as a piping space 102 of the air supply duct 3.

Further, the plurality of air supply fans 4 are respectively provided for one port of the air supply duct 3. Then, air is supplied to the plurality of rooms of the house via the air supply duct 3.
The supply air blower 4 is rotated by using a direct current (DC) motor as a drive source. The number of installations is the same as the number of air-conditioned rooms 42. The wall surface 12b and the floor surface 16 of the air conditioner room 1 are formed with through holes (not shown) through which the air supply ducts 3 pass the number of the air-conditioning target rooms 42. After passing the air supply duct 3 through these through holes, one port of the air supply duct 3 is connected to each air supply blower 4.

(Air supply duct 3)
As shown in FIG. 1, the air supply duct 3 supplies air conditioned in the air conditioner room 1 to each room of the house.
The air supply duct 3 is preferably a low pressure loss flexible duct. The air supply duct 3 is piped linearly or in a curved shape having a large curvature so that resistance (ventilation resistance) is not applied to the air as much as possible when passing through the air.

  In this embodiment, one of the air supply ducts 3 is connected to the air supply blower 4, but the other air supply duct 3 is connected to a plurality of living rooms 42, which are air-conditioning target rooms of the house, and the floor below. 36 and is connected to the blow-out grill 50 provided in each. Then, the air conditioned in the air conditioner room 1 (hereinafter referred to as air supply SA) is blown out from the blow-out grill 50 toward the living room 42 and the underfloor 36 via the air supply duct 3.

(Air supply SA)
The air supply SA shown in FIG. 1 and FIG. 2 is a mixture of the outside air OA, the attic air, and the air conditioner air that flowed into the air conditioner room 1 via the air supply duct 31 in the air conditioner room 1. Air. Moreover, the installation location of the blowing grill 50 in the living room 42 or the like is preferably the window side with a large load.

(Exhaust duct 32)
The exhaust duct 32 shown in FIG.1 and FIG.2 is a duct which exhausts the air of a house toward the outdoors.
The exhaust duct 32 uses, for example, an exhaust grill 40 installed in a utility 34, an underfloor 36, or the like, which is a room in which facilities such as a washing machine, a dryer, and an iron are collectively installed, as a starting point of the exhaust flow.

  Then, the exhaust grill 40 is used as a base point, and then passes through the heat exchange air unit 14 provided in the middle of the exhaust duct 32. Then, the air in a house is discharged | emitted outside from the deep hood 122 installed in the discharge port 11 for the discharge of the outside air formed in the outer wall of a house.

  The heat exchange air unit 14, the air supply duct 31, and the exhaust duct 32 are insulated to prevent condensation. In addition, it is preferable that the heat exchange air unit 14 calculates the ventilation resistance of the air supply duct 31 and the exhaust duct 32 and selects a specification that can sufficiently secure the air volume.

  Further, in the air conditioner room 1, in order to prevent a short circuit that is a phenomenon in which air is circulated in a narrow range because the positions of the air conditioner, the exhaust port, and the air supply port are too close, In that case, it is preferable that the installation positions of the air conditioner 2, the exhaust port 41, and the outside air introduction port 311 are separated as much as possible.

(Air circulation)
Next, air circulation when the central air conditioning system S1 having such a configuration is used will be described mainly with reference to FIGS.
When the air supply blower 4 is driven by a DC motor, air circulation starts from the air conditioner room 1. At the same time, the air conditioner 2 is also driven, and the air conditioner air flows out to the mixing unit 33. Since the air supply blower 4 is driven by a DC motor, the attic air and the outside air OA also flow out toward the air conditioner room 1 from the attic air inlet 400 and the outside air inlet 311 respectively.

  Then, the air-conditioner air, the attic air, and the outside air OA all collide with the drooping wall 6 and then rebound, so that these three airs are mixed together. As a result, in the winter season, the attic air and the outside air OA are warmed by the air-conditioner air, and on the contrary, in the summer season, the air is cooled. The mixed portion is filled with air of uniform temperature (hereinafter, mixed air) with the mixed air.

  Since the supply air blower 4 is already driven by the DC motor, the mixed air flows toward the supply air blower 4. When the mixed air flows, the amount of the mixed air that fills the mixing unit 33 decreases. However, since the reduced amount of 3 air is compensated, the amount of the mixed air is kept constant.

  However, the outside air OA passes through the heat exchange air unit 14 after the dust contained in the outside air OA is removed by the filter unit 13 shown in FIGS. Therefore, the outside air OA introduced into the air conditioner room 1 from the inlet 311 of the air conditioner room 1 is not much different from the set temperature of the air conditioner 2.

Then, the mixed air flowing toward the air supply blower 4 is sent to the living rooms 42 and the underfloor 36 via the air supply duct 3.
The supply air SA sent to the living room 42 then passes through the hole 46 from the vent 43 of the living room 42 and then reaches the utility 34 via the vent 35. Thereafter, the supply air SA is exhausted to the outside as exhaust air EA through the exhaust air duct 32 from the exhaust grill 40 installed in the utility 34 as the indoor air RA, through the exhaust duct 32 therefrom. .

  In addition, the supply air SA sent to the underfloor 36 from the blowout grill 50 shown in FIG. 1 passes through the duct 32 from the exhaust grille 40 installed in the underfloor 36 and then passes through the heat exchange air unit 14. It is discharged outdoors as exhaust EA.

  Furthermore, the indoor air RA of the living room 42 and the like is sent to the air conditioner room 1 via the communication path 47 (see FIG. 1) of the hall 46 in addition to flowing to the utility 34. In this way, air circulates between the inside and outside of the house.

(Action / Effect)
Next, operational effects will be described.
According to the air conditioning system S1, as described above, the air-conditioner air, the attic air, and the outside air OA all collide with the drooping wall 6 and then rebound, so that these three airs are mixed.

  As a result, regardless of summer or winter, the mixing unit 33 (see FIGS. 3 and 4) is filled with air of uniform temperature (hereinafter, mixed air). Since the supply air blower 4 is already driven by the DC motor, the mixed air flows toward the supply air blower 4.

Then, there is a ventilation space S that is a narrow path of about 30 to 50 centimeters in the middle of flowing toward the air supply blower 4, and a plurality of the air supply blowers 4 pass through the ventilation space S from the mixing unit 33 side. The flow of air to the supply air blower 4 side can be performed. Therefore, in the air conditioner room 1 (
In particular, turbulence occurs in the ventilation space S). Since turbulent flow occurs, the air-conditioning air, the attic air, and the outside air OA are further mixed.

  The air supply blower 4 is connected to one port of a plurality of ducts that connect the air-conditioned air chamber 1 to the residential room 42 and other rooms, and is thus air having a substantially uniform temperature through the ducts. Mixed air is sent to each room and circulates throughout the house.

For this reason, the temperature difference between rooms can be decreased.
As described above, according to the present invention, it is possible to provide a residential environment that does not have an extreme temperature difference for each room even under the influence of sunshine hours and other external environments.
Therefore, in this system S1, a particularly desirable living environment can be provided to users who are sensitive to changes in temperature, such as women, elderly people, and infants.

  Moreover, although a commercial household air conditioner with a small air conditioner capacity is used as the air conditioner of the central air conditioning system, in the present system S1, a plurality of air supply ducts 3 are respectively The other mouth is installed so as to be guided to a plurality of rooms of the house.

  In the present system S1, a large amount of air is supplied to each room of the house by the plurality of air supply blowers 4 respectively provided to the one port of the air supply duct 3. For this reason, even if the temperature of the air volume coming out from the air outlet of the air conditioner is not so low, the air volume supplied to each room by the air supply blower 4 can be felt cool even in summer.

(Example 2)
Next, Embodiment 2 will be described with reference to FIGS.
The second embodiment differs from the first embodiment only in the place where the mixing unit and the air supply blower 4 are installed.
Therefore, only different parts will be described, and the same parts as those in the first embodiment are denoted by the same reference numerals and description thereof will be omitted.

  When this Example 2 enumerates points different from Example 1, as can be seen from FIGS. 9 and 10, (1) the air conditioner 2 is also installed on the air supply fan mounting wall 44, and (2) the air conditioner room The attic air inlet 400 is provided at a position facing the air conditioner 2 in the side wall 111 of (1). (3) There is no drooping wall 6; (4) (5) The horizontal plate is a foldable plate-like material.

These will be described in detail below.
As shown in FIGS. 9 to 11, the supply air blower mounting wall 44 is provided with a total of 15 supply air blowers 4 (see FIG. 13) in a single stage with three supply air blowers 4 separated in three stages. . In addition to this, the air conditioner 2 is also installed at the uppermost part of the air supply fan mounting wall 44.

  Of the side walls of the air conditioner room 1, as shown in FIGS. Therefore, the side wall 111 </ b> A is a side wall facing the air conditioner 2, and is therefore referred to as a counter side wall.

  As described above, the hanging wall 6 is not provided in the second embodiment. However, as shown in FIGS. 9, 10 and 14, a foldable plate-like material 61 is provided directly below the air conditioner 2 as an defining plate instead of the hanging wall 6. Specifically, as shown in FIG. 10, the plate-like member 61 rotates clockwise and counterclockwise between a horizontal state and a vertical state with a hinge (not shown) as an axis.

  When the plate-like material 61 is in a horizontal state, the horizontal state is maintained by a detachable fixing means (not shown). And when the plate-shaped material 61 exists in a horizontal state, the ventilation space S which is a narrow path of about 30-50 cm is formed between the front-end | tip of the plate-shaped material 61, and the side wall 111A. Thereby, the mixing part 300 is formed in the upper part of the air-conditioner room 1 (refer FIG. 10). The plate member 61 forming the mixing unit 300 is more compact than the drooping wall 6.

  In the case of the second embodiment, it is preferable that the outside air inlet (not shown) is installed above the side wall 111 </ b> A according to the installation height of the air conditioner 2.

  Furthermore, in the case of Example 2, in the mixing unit 300 in the upper part of the air conditioner room 1, the outside air taken in from the outside air inlet, the attic air taken in via the dust removal filter 401 from the attic air inlet 400, and the air conditioner Air mixes. The mixed air is taken in by the air supply blower 4 and is sent toward the air supply duct 3.

  The subsequent air flow is the same as in the first embodiment. Moreover, since both are installed so that the attic air inlet 400 may oppose the air conditioner 2 (refer FIG. 10), the attic air taken in from the attic air inlet 400 and air-conditioner air collide. Therefore, the mixing efficiency is good.

  Moreover, in Example 2, since the drooping wall 6 does not exist and the plate-shaped material 61 for forming the mixing part 300 is considerably smaller than the drooping wall 6, the air conditioner room 1 is made compact. Can do. In Example 2, even if the air conditioner room 1 is compact, the supply air blower 4 is attached to the supply air blower mounting wall 44 in three stages to form a multistage system. Therefore, the number of the air supply fans 4 is not inferior and can be installed in large numbers. Therefore, the air conditioning effect is not inferior to that in the first embodiment.

Other functions and effects are the same as those in the first embodiment.
Note that the plate-like material 61 that is the defining plate may be stretchable by a bellows.
Moreover, in Example 2, the inspection port 17 is formed in the opposing side wall 111 </ b> A (see FIGS. 12 and 13) of the air conditioner room 1.

Example 3
Next, Embodiment 3 will be described with reference to FIGS.
The third embodiment differs from the first embodiment in the installation position of the air conditioner 2 and the size of the attic air inlet 400.
Therefore, only parts different from the first embodiment will be described, and the same parts as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  The air conditioner 2 according to the third embodiment is positioned at the uppermost position of the hanging wall 6 (see FIGS. 15 and 17). An attic air inlet 400 having a slightly larger vertical width than the height of the air conditioner 2 is formed on the side wall 111 so as to face the air conditioner 2. Further, as in the case of the second embodiment, although not shown, it is preferable that the outside air inlet is installed above the side wall 111 in accordance with the installation height of the air conditioner 2.

  In the case of Example 3, both are installed so that the attic air inlet 400 faces the air conditioner 2. Therefore, since the attic air taken in from the attic air inlet 400 collides with the air-conditioner air, the mixing efficiency is improved.

  In Example 3, the inspection port 17 is formed in one side wall 111B (see FIG. 19) of the air conditioner room 1, as shown in FIG.

(Comparative example)
20-22 is a figure which compares and shows the case where this system is employ | adopted, and the case where it is not so.

  FIG. 20 is a temperature-time diagram of each room before the present system is applied, and FIG. 21 is a temperature-time diagram of each room to which the present system is applied. FIG. 22 is a comparison table for explaining the effects of the present invention.

  20 and FIG. 21, the left vertical axis indicates the room temperature in each room, the right side indicates the number assigned to the sampled air supply fan 4, and the horizontal axis indicates the measurement time. 20 and 21, a region a1 shows a state where the air conditioner 2 is stopped.

  What the region a1 means is that there is no difference in the temperature of each room connected to any of the air supply fans 4 via the air supply duct 3. This is because the air supply fan 4 has no temperature difference since the air conditioner 2 is not operating in the air conditioner room 1.

  Further, in FIG. 20, the temperature outside the area a1 indicates the room temperature in each room when the air conditioner 2 is operating. It can be seen that among the plurality of graph lines in FIG. 20, the lower the temperature is, the higher the temperature is.

  This is the positional relationship of the air supply blower 4 with the air conditioner 2, and the air supply blower 4 related to the lower graph line is closer to the air conditioner 2 and the air supply blower related to the upper graph line. 4 means that the distance from the air conditioner 2 is a long distance.

Furthermore, in FIG. 20, it can be seen that the temperature difference between the lower one and the upper one of the plurality of graph lines is larger than that in the temperature-time diagram of FIG. .
In FIG. 21, a region a2 is a state where the power supply of the air conditioner 2 is turned on / off.

  Areas other than the areas a1 and a2 in FIG. 21 indicate the Celsius temperature of each room when the air conditioner 2 is operating. And it turns out that the temperature difference of what is on the lower side and what is on the upper side among several graph lines is small compared with the case of FIG. This is because the outside air OA, the attic air, and the air-conditioner air are mixed in the mixing unit 33, and the mixed air formed thereby is supplied almost uniformly to any of the plurality of air supply blowers 4. is there.

  FIG. 22 is a chart showing the temperature of the air sucked into all the supply air blowers 4 as the sample when this system is adopted and when it is not. What can be seen from this chart is as follows.

Room temperature 26.1 due to air supply from the supply air blower 4 of No. 2 which was the highest temperature before improvement
The temperature of the room 23 by air supply from the supply fan 4 of NO.
. The temperature difference from 5 ° C is 2.6 ° C.

On the other hand, when this system was adopted, it was improved as follows.
That is, the temperature of the room 25.2 ° C. due to the supply of air from the supply fan 4 of NO.4, which was the highest temperature after improvement, and the supply of air from the supply fan 4 of NO.3, which was the lowest temperature after improvement. Since the temperature difference from the room temperature of 24.8 ° C. is 0.4 ° C., the difference between the room Celsius temperature of each room is higher when this system is adopted, as compared with FIGS. 20 and 21. Is small.

In other words, as shown in FIG. 22, the variation of the average value of the air temperature sucked into the supply air blower 4 (difference between the maximum value and the minimum value) was greatly improved from 2.7 ° C. to 0.4 ° C. I understand that.
Further, it can be seen that the average value of the maximum temperature at the time of each measurement (every 2 minutes) on the horizontal axis in FIGS. 20 and 21 is greatly improved from 2.7 ° C. to 0.4 ° C.

S1 Central air conditioning system 1 Air conditioner room 2 Air conditioner (air conditioner)
3 Air supply duct (duct)
4 Air supply blower 6 Hanging wall (drawing board)
10 Outside air intake port 11 Outlet port 12b Wall surface 13 Filter unit (filter)
14 heat exchange air unit 15 louver 16 floor 17 inspection port 21 indoor unit 22 outdoor unit 31 air supply duct 32 exhaust duct 33 mixing unit 34 utility 35 vent 36 under floor 40 exhaust grille 41 exhaust port 42 room 43 vent port 44 air supply Blower mounting wall 46 Hall 47 Communication path 50 Blowing grill (blower)
61 Plate material (horizontal plate, definition plate)
100 Dispersion chamber 102 Piping space 111 Side wall (one wall surface of air conditioner room)
111A Opposite side wall 121 Deep hood 122 Deep hood 300 Mixing section 311 Outside air inlet (outside air inlet)
400 Attic air inlet (external air inlet)
401 Dust removal filter EA Exhaust OA Outside air RA Indoor air SA Supply air S Ventilation space a1, a2 Area on graph

Claims (9)

An air conditioner room where the air conditioner is installed;
An external air intake port that is formed in this air conditioner room and takes in external air that is at least air outside the air conditioner room, and
An air conditioner installed in an air conditioner room and performing air conditioning of the air conditioner room with external air taken in from the external air intake port;
A plurality of ducts, one of which is installed on the air conditioner room side and the other of which is led to each room of the house;
An air conditioning system including a blower provided in each of the plurality of ducts,
In the air conditioner room,
The air conditioning system which has a mixing part which mixes the said external air and outflow air before the outflow air which flows out from the said external air and an air conditioner is sent toward one opening of the said duct. The mixing unit is a part of a room partitioned by a defining plate that defines the air conditioner room,
The defining plate is suspended in the air conditioner room, and forms a ventilation space with the floor surface of the air conditioner room when the defined plate is suspended.
In the air conditioner room, the air conditioner is installed on one side and the external air intake port is formed on the one side of the partition plate, and one side of the duct is formed on the other side. The air conditioning system according to claim 1, wherein:   The air conditioner is installed at a location above the ventilation space on one side of the partition plate, and the external air intake port is provided above the air conditioner. The air conditioning system described in.   In the air conditioner room, the air conditioner and the plurality of blowers are installed in an up-down direction with the air conditioner at the top, and the outer wall of the wall surface of the air conditioner room has the external wall facing the air conditioner. An air intake port is formed, the defining plate is horizontally disposed directly below the air conditioner, and the ventilation space is formed between the defining plate and the opposite side wall, thereby the mixing unit is The air conditioning system according to claim 1 to be formed.   The air conditioning system according to claim 4, wherein the defining plate is a foldable plate material.   6. The air conditioning system according to claim 4, wherein the plate member is positioned between a horizontal state and a vertical state with a hinge as an axis.   The air conditioning system according to claim 5, wherein the plate plate is capable of extending and contracting the plate-like material by bellows.   In the side surface of the defining plate, the air conditioner is installed at a location above the ventilation space, and the external air intake port is provided at a location facing the air conditioner in the wall surface of the air conditioner room. The air conditioning system according to claim 2, wherein the air conditioning system is provided. An air conditioner room installed in a house and having an air conditioner,
The side wall to which the air conditioner is connected, or the opposite wall to which the air conditioner is connected, facing the side wall;
A fan to which the duct is connected,
An air-conditioned air chamber having a mixing unit that mixes the external air and the outflow air before the outside air that is outside the air-conditioner room and the outflow air that flows out of the air conditioner are sent to the duct.

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