JP4424113B2 - Ventilation system and housing structure - Google Patents

Description

The present invention includes a ventilation system including an air supply unit that supplies outside air into the room, a bathroom air conditioner that exhausts air in the bathroom to the outside and controls air conditioning in the building, and the ventilation system. Concerning housing structure.

  In recent years, the airtightness of houses has increased, and the concentration of carbon dioxide becomes too high unless sufficient ventilation is provided. Especially in newly built houses, the concentration of formaldehyde and volatile organic compounds (VOC) is high It may become too much. In order to solve this problem, for example, a house air ventilating apparatus disclosed in Patent Document 1 is used to ventilate a house.

  This bathroom air conditioner performs ventilation of other rooms (toilet, toilet, etc.) in addition to ventilation of the bathroom.

  There is also a ventilator for ventilating a house using a total heat exchange type ventilator equipped with an air supply fan and an exhaust fan (see Patent Document 1).

Such a ventilator supplies outside air to each room through a duct, sucks room air from a return air port, and discharges it to the outside, thereby ventilating a house.
Japanese Patent Laid-Open No. 10-281523

  By the way, a range hood fan is provided in a kitchen or the like, and the exhaust amount of the range hood fan is generally larger than the exhaust amount of the bathroom air conditioner or the total heat exchange type ventilator described above.

  For this reason, in such a ventilation system, when a range hood fan provided in a kitchen or the like is driven, the total displacement of the exhaust amount by the range hood fan and the exhaust amount by the total heat exchange type ventilator is The total heat exchange type ventilator will exceed the amount of air supplied, resulting in negative pressure in the house. That is, the balance between the air supply amount and the total exhaust amount is lost. As a result, there are problems such as heavy opening / closing operations of doors and windows, and wind noise generated by the wind flowing in through the gaps of the windows. This problem is particularly noticeable in highly airtight houses.

An object of the present invention is to provide a ventilation system in which the balance between the air supply amount and the total displacement is not lost. Further, in a house by driving the hood fan is to provide a free ventilation system be become a negative pressure.

The invention of claim 1 is an air supply means for supplying outside air into a building, and a bathroom air conditioner that is provided in a bathroom in the building and exhausts the air in the bathroom to the outside and performs air conditioning control in the building. A ventilation system comprising a device and a range hood fan provided in a kitchen in the building and exhausting the air in the kitchen to the outside,
When the range hood fan starts operating with the air supply means and the bathroom air conditioner operating,
The bathroom air conditioner captures an operation start signal from the range hood fan, and reduces the exhaust amount by the bathroom air conditioner, whereby the air supply amount by the air supply means, the exhaust amount by the range hood fan, and Control is performed so that the total exhaust amount of the exhaust amount by the bathroom air conditioner is equal.

The invention of claim 2 is characterized in that the bathroom air conditioner is a device separate from the air supply means, and controls the air supply means in conjunction with the operation of the bathroom air conditioner.

The invention of claim 3 is a ventilation system provided with heat exchange means for exchanging heat between outside air and indoor exhaust air.

The invention of claim 4 is a residential structure provided with the ventilation system according to any one of claims 1 to 3 .

  According to the present invention, the balance between the air supply amount and the total exhaust amount is not lost.

Moreover, even if a range hood fan is driven, it can prevent that the inside of a house becomes a negative pressure.

  Embodiments of a ventilation system according to the present invention will be described below with reference to the drawings.

[First embodiment]
FIG. 1 shows a ventilation system 1 according to the present invention. The ventilation system 1 is provided with a bathroom air-conditioning equipment 1 0 provided on the ceiling of the bathroom 2 (not shown), and an intermediate duct fan (air supply means) 40 provided on the ceiling of the corridor 3 (not shown) ing. Furthermore, the range hood fan 7 0 is provided in the kitchen (kitchen) 4.
[Bathroom air conditioner 10]
As shown in FIGS. 2 and 3, the bathroom air conditioner 10 includes a main body case 12 attached in the ceiling T of the bathroom 2. The lower surface of the main body case 12 is provided with first and second suction ports 13 and 14 for sucking air in the bathroom 2 and an outlet 15 for blowing the air sucked from the second suction port 14 into the bathroom. ing. A heater 16 such as a PTC heater (heater with a self-temperature control function) is attached in the air outlet 15, and the air blown out from the air outlet 15 is heated by the heater 16.

  On one side surface of the main body case 12 are provided first and second air inlets 18 and 19 for sucking air from other rooms (toilet, toilet, etc.). An exhaust port 20 for exhausting air sucked from the suction port 13 and the first and second intake ports 18 and 19 is provided. The exhaust port 20 communicates with the outside through an exhaust duct 21 connected to the connection duct 20A. The first and second air inlets 18 and 19 communicate with the washroom 5 and the toilet 6 via ducts 22 and 23 connected to the connection ducts 18A and 19A, respectively. Reference numeral 25 denotes a vent hole connected to the duct 22 and provided on the ceiling (not shown) of the washroom 5 or the like. Reference numeral 26 denotes an air vent provided in a ceiling (not shown) of the toilet 6 connected to the duct 23.

In the main body case 12, a sirocco fan (ventilation fan) 28 for ventilation that sucks air from the first suction port 13 and the first and second suction ports 18, 19 and blows it to the exhaust port 20, and a second suction port. A circulation sirocco fan 29 for blowing air sucked from 14 to the blowout port 15 is provided. The sirocco fan 28 is rotated by the motor M1, and the sirocco fan 29 is rotated by the motor M2.
[Intermediate duct fan 40]
As shown in FIGS. 4 and 5, the intermediate duct fan 40 has a main body case 41 suspended in the attic, a sirocco fan (air supply fan) 42 provided in the main body case 41, and the sirocco fan 42. And a high-performance filter 43 detachably attached to the left side surface of the main body case 41. A drain pan 44, which will be described later, and a lid 45 that can be opened and closed are provided on the bottom of the main body case 41. By opening the lid 45 to the position of the chain line shown in FIG. 5, the high-performance filter 43 can be taken out. ing. The high performance filter 43 includes a pre-filter 43A that removes dust and a NO _x filter 43B that removes NO _x (nitrogen oxide).

  The drain pan 44 receives and accumulates water droplets condensed in the main body case 41, and the accumulated water is discharged outside through a hose (not shown).

  Further, an air inlet 46 is formed on one side surface (left side surface) of the main body case 41 so as to face the high-performance filter 43, and the air inlet 46 communicates with the outside through the air intake duct 47 connected to the connection duct 47A. is doing. When the sirocco fan 42 rotates, outside air is sucked from the air inlet 46 through the air intake duct 47, and the sucked outside air is blown toward the right side surface of the main body case 41 by the sirocco fan 42. .

  A chamber 50 is attached to the other side surface (right side surface) of the main body case 41, and outside air blown by the sirocco fan 42 is sent into the chamber 50.

  Three air supply ports 51, 52, 53 are formed on the right side surface of the chamber 50, and an air supply port 54 and an air supply port are provided on one end surface (upper surface in FIG. 4) and the other end surface (lower surface in FIG. 4) of the chamber 50. A mouth 55 is formed. The air supply port 51 communicates with the western-style room (room) 7 shown in FIG. 1 through the air supply duct 56 connected to the connection duct 56A, and the air supply port 52 passes through the air supply duct 57 connected to the connection duct 57A. The air supply port 53 communicates with the Japanese-style room (room) 9 via the air supply duct 58 connected to the connection duct 58A. The air supply port 54 communicates with the Western-style room (room) 60 via the air supply duct 59 connected to the connection duct 59A, and the air supply port 55 communicates with the western-style room via the air supply duct 61 connected to the connection duct 61A. It communicates with (room) 62.

In FIG. 1, reference numeral 63 denotes an air supply grill connected to the air supply duct 56, and the air supply grill 63 is provided on the wall of the western room 7. Reference numeral 64 denotes an air supply grill connected to the air supply duct 57, and the air supply grill 64 is provided on the wall of the dining room 8. An air supply grill 65 is connected to the air supply duct 58, and the air supply grill 65 is provided on the wall of the Japanese-style room 9. Reference numeral 66 denotes an air supply grill connected to the air supply duct 59, and the air supply grill 66 is provided on the wall of the western room 60. Reference numeral 67 denotes an air supply grill connected to the air supply duct 61, and the air supply grill 67 is provided on the wall of the western room 62.
[Range hood fan 70]
As shown in FIG. 6, the range hood fan 70 includes an exhaust fan 71, a motor M <b> 4 that rotates the exhaust fan 71, and the like.
[Control system]
FIG. 7 is a block diagram showing the configuration of the control system of the ventilation system 1. In FIG. 7, reference numeral 30 denotes a control device for the bathroom air conditioner 10, and the control device 30 controls driving of the motors M <b> 1 and M <b> 2 and energization of the heater 16 based on the operation of the remote controller 31. Reference numeral 80 denotes a motor drive circuit for the intermediate duct fan 40, and this motor drive circuit drives the motor M3 based on a control signal from the control device 30 of the bathroom air conditioner 10. Reference numeral 90 denotes a drive circuit that drives the motor M4 when the power switch 91 is turned on. The drive circuit 90 sends an operation signal indicating that the range hood fan 70 is operated when the motor M4 is driven. It outputs to the control apparatus 30 of the air conditioner 10.

This operation signal is obtained from, for example, a micro switch for detecting that the power switch 91 is turned on, a coil for detecting a current flowing through the motor M4, or the like.
[Operation]
Next, operation | movement of the ventilation system 1 comprised as mentioned above is demonstrated.

  Now, assume that ventilation of each room by the bathroom air conditioner 10 and air supply to each room by the intermediate duct fan 40 are performed.

  That is, the ventilation mode is set by the operation of the remote controller 31 of the bathroom air conditioner 10, and the motor M1 is driven. The sirocco fan 28 is rotated by driving the motor M1, and the rotation of the air in the bathroom 2 is caused by this rotation. The air in the bathroom 5 and the toilet 6 passes through the ventilation louvers 25 and 26 and the ducts 22 and 23, and the first and second air intakes 18 and 19 of the bathroom air conditioner 10 are sucked in from the first suction openings 13 of the tenth. Will be sucked into.

  The air sucked into the first suction port 13 and the first and second suction ports 18 and 19 is exhausted to the outside through the exhaust port 20 and the exhaust duct 21 by the rotation of the sirocco fan 28.

  By the way, the bathroom 2, the washroom 5 and the toilet 6 communicate with each of the rooms 7-9, 60, 61 through a louver or undercut provided on the door, so that these rooms 7-9, 60, 61 Air is also exhausted.

  On the other hand, the motor drive circuit 80 of the intermediate duct fan 40 is operated by the signal of the control device 30 of the bathroom air conditioner 10 to drive the motor M3, and the outside air passes through the intake duct 47 to the intake port 46 by driving of the motor M3. Is sucked in, and the sucked outside air passes through the high-performance filter 43, where dust and NOx are removed, and the removed outside air is blown into the chamber 50 by the sirocco fan 42. The outside air blown into the chamber 50 is supplied to the rooms 7-9, 60, 61 through the air supply ports 51-55 and the air supply ducts 56-59, 61.

  The fresh air supplied to each of the rooms 7 to 9, 60, 61 is supplied to the bathroom 2, the washroom 5 and the toilet 6 through a louver or undercut provided on the door.

  And since the rotation speeds of the motors M1 and M3 are set so that the amount of air exhausted by the bathroom air conditioner 10 and the amount of air supplied by the intermediate duct fan 40 are equal, when normal regular ventilation is performed The balance between the amount of exhaust and the amount of air supply is balanced, and the rooms 7-9, 60, 61, the bathroom 2, the washroom 5, and the toilet 6 may become negative pressure. Absent.

  And step 1 of the flowchart shown in FIG. 8 is repeatedly performed until the range hood fan 70 is drive | operated.

  When the range hood fan 70 is operated by turning on the power switch 91, it is determined as YES in step 1, and the process proceeds to step 2.

  The air in the kitchen 4 is exhausted by the operation of the range hood fan 70, and the total exhaust amount of the exhaust amount by the bathroom air conditioner 10 and the exhaust amount by the range hood fan 70 is larger than the supply amount by the intermediate duct fan 40.

  That is, conceptually shown in FIG. 9, the balance of the room A is balanced by the exhaust from the bathroom air conditioner 10 and the supply from the intermediate duct fan 40, but the balance is lost due to the exhaust by the range hood fan 70. The room A becomes negative pressure.

  In step 2, the exhaust amount by the bathroom air conditioner 10 is reduced or the air supply amount by the intermediate duct fan 40 is increased.

  As a result, the total exhaust amount of the exhaust amount of the bathroom air conditioner 10 and the exhaust amount of the range hood fan 70 is prevented from being larger than the supply amount of the intermediate duct fan 40. That is, even if the range hood fan 70 is operated, the exhaust amount of the bathroom air conditioner 10 shown in FIG. 9 is reduced, or the amount of air supplied to the intermediate duct fan 40 is increased, so that the room A can be balanced. Become. In other words, the intermediate duct fan 40 and the bathroom air conditioner 10 are controlled so that the balance between the air supply amount of the intermediate duct fan 40 and the total exhaust amount of the bathroom air conditioner 10 and the range hood fan 70 is not lost.

  This control prevents negative pressure inside the house, prevents heavy opening and closing of doors and windows, prevents air from flowing into the room through the gaps in the windows, and There is no wind noise.

  In addition, the outside air can be concentrated and cleaned by the high performance filter 43 provided in the intermediate duct fan 40, and the filter can be replaced at one place.

  When the heating mode is set by the remote controller 31, only the motor M2 is driven and the heater 16 is energized. As the motor M2 is driven, the sirocco fan 29 is rotated and the air in the bathroom is sucked from the second suction port 14 and blown out from the air outlet 15 to the bathroom 2. Since the air blown out from the air outlet 15 is heated by the heater 16, the bathroom 11 is heated.

  When the ventilation mode is set, only the motor M1 is driven, and the heater 16 is not energized. By driving the motor M1, air is exhausted from the bathroom 2, the washroom 5, the toilet 6, and the rooms 7 to 9, 60, 61 as described above.

  When the cool air mode is set, energization of the heater 16 is stopped and only the motor M2 is driven. That is, air is blown out from the air outlet 15, and the bathroom air conditioner 10 functions as a fan.

  The ventilation system 1 of 1st Example is performing the continuous ventilation which ventilates continuously or intermittently, and satisfy | fills the predetermined (regulation) ventilation volume of the area of the area which needs ventilation in the whole house. . The predetermined ventilation amount is, for example, 0.5 times / hour as the number of ventilations. However, this ventilation frequency may be switched by providing a selection means such as a switch so that the air volume is low, for example, 0.3 times / hour in winter. The predetermined (regulated) ventilation amount only needs to satisfy at least one of the supply amount and the exhaust amount.

  According to the ventilation system 1 of the first embodiment, it is possible to prevent negative pressure in the house while always satisfying the predetermined ventilation frequency.

The bathroom air conditioner 10 of the first embodiment has two sirocco fans 28 for ventilation and sirocco fans 29 for circulation. However, ventilation, heating, cool air, etc. can be obtained by switching one sirocco fan and a damper. The bathroom air conditioner which can be used may be sufficient.
[Second Embodiment]
FIG. 10 is a block diagram showing the configuration of the control system of the ventilation system of the second embodiment. In FIG. 10, 101 is an air volume detection device (air volume detection means) for detecting the exhaust air volume of the bathroom air conditioner 10, and this air volume detection device 101 is composed of, for example, a fan, a shutter or the like, and is connected to the connecting duct 20A shown in FIG. And provided in the exhaust duct 21. Then, the exhaust air volume is detected from the rotational speed of the fan and the opening of the shutter.

110 is an air volume detection device (air volume detection means) for detecting the air supply amount of the intermediate duct fan 40. The air volume detection device 110 is composed of, for example, a fan, a shutter, and the like. It is provided in the duct 47. Then, the exhaust air volume is detected from the rotational speed of the fan and the opening of the shutter.
[Operation]
Next, the operation of the second embodiment will be described.

  It is assumed that so-called regular ventilation is performed in which ventilation of each room by the bathroom air conditioner 10 and supply of air to each room by the intermediate duct fan 40 are performed. And as shown in FIG. 11, the exhaust_gas | exhaustion amount by the bathroom air conditioner 10 and the air supply amount by the intermediate | middle duct fan 40 are equal, and the exhaust_gas | exhaustion and air supply are balanced.

  When the outdoor wind (outside air wind) is weak, the exhaust amount of the bathroom air conditioner 10 and the air supply amount of the intermediate duct fan 40 are substantially constant. In step 10 of the flowchart shown in FIG. The processing operation of step 10 is repeatedly performed until the air blows.

  As shown in FIG. 11, when strong wind (outside air wind) blows as shown by the arrow Q1, the exhaust amount by the bathroom air conditioner 10 is greatly reduced, and the air supply amount of the intermediate duct fan 40 is greatly increased. That is, the air volume detected by the air volume detection devices 101 and 110 fluctuates greatly, so that it is determined no in step 10 and the process proceeds to step 11.

  In step 11, the airflow of the device whose airflow has increased is reduced. That is, the driving force of the motor M3 of the intermediate duct fan 40 is reduced, so that the air supply amount is reduced and returned to the original air supply amount. In addition, it is determined that the load of the device whose airflow has decreased is increased, and the airflow of the device is decreased. That is, the driving force of the motor M1 of the bathroom air conditioner 10 is reduced, and thus the displacement is reduced.

  On the contrary, when strong wind blows as shown by the arrow Q2, the exhaust amount by the bathroom air conditioner 10 increases greatly, and the air supply amount of the intermediate duct fan 40 decreases greatly. And the air volume of the apparatus with which the air volume increased is reduced. That is, the driving force of the motor M1 of the bathroom air conditioner 10 is reduced, so that the exhaust amount is reduced and returned to the original exhaust amount. In addition, it is determined that the load of the device whose airflow has decreased is increased, and the airflow of the device is decreased. That is, the driving force of the motor M3 of the intermediate duct fan 40 is reduced, and thus the air supply amount is reduced.

  Thus, when the supply air volume by the intermediate duct fan 40 or the ventilation air volume by the bathroom air conditioner 10 fluctuates, the motor M3 of the intermediate duct fan 40 satisfies the specified air volume (predetermined ventilation volume). Since the driving force and the driving force of the motor M1 of the bathroom air conditioner 10 are reduced, energy can be saved without being affected by strong external wind.

Ventilation system according to the second embodiment, based on the result of detection from the air flow detecting device 101, 110, and bathroom air conditioning equipment 1 0 As one either of the air supply amount and exhaust amount approaches a predetermined ventilation intermediate A duct fan (air supply means) 40 is controlled. By doing in this way, it does not become an excessive ventilation quantity, and also can reduce the load to motors M1 and M3.

  The ventilation system of the second embodiment performs continuous ventilation that continuously or intermittently ventilates in the same manner as the first embodiment, and sets a predetermined (prescribed) ventilation volume of the area that needs ventilation in the entire house. It comes to meet. The predetermined ventilation amount is, for example, 0.5 times / hour as the number of ventilations. However, this ventilation frequency may be switched by providing a selection means such as a switch so that the air volume is low, for example, 0.3 times / hour in winter. The predetermined (regulated) ventilation amount only needs to satisfy at least one of the supply amount and the exhaust amount.

  That is, the motors M1 and M3 are controlled so that at least one of them satisfies a predetermined ventilation frequency in response to a change in pressure such as the outside air pressure.

  In the second embodiment, the driving force of both the motor M1 of the bathroom air conditioner 10 and the motor M3 of the intermediate air duct fan 40 for supplying air is reduced when the environment changes such as the wind pressure of the outside air. If either one of the amounts is controlled so as to have the prescribed air volume, the driving force of only one of the motors M1 and M3 may be adjusted.

The bathroom air conditioner in the first and second embodiments may be an exhaust-type intermediate duct fan, and may be composed of a plurality of ventilation devices instead of a single one. Similarly, the air supply means may be an air supply device such as a pipe fan, or may be composed of a plurality of air supply devices instead of a single air supply device.
[Third embodiment]
FIG. 13 shows a ventilation device (heat exchange type ventilation unit) 501 used in the ventilation system of the third embodiment.

  The main configuration of the ventilator 501 as an air conditioner is to introduce outside air into the main body case 502 disposed above or above the indoor ceiling plate 503 to supply air outside the building (outside air) and supply it indoors. An air passage AR1 and an exhaust air passage AR2 for taking in indoor air and exhausting it outside the building are formed.

  In addition, at the intersection where the outside air introduction air path AR1 and the exhaust air path AR2 intersect each other, heat is exchanged between the outside air passage P1 through which air outside the building passes and the exhaust passage P2 through which room air passes. An exchange element 511 is provided.

  The main body case 502 is configured to heat the indoor air suction surface F2 in which the air inlet for introducing the indoor air in the exhaust passage P2 of the heat exchange element 511 is open while the main body case 502 is installed above or above the ceiling plate 503. The outside air passage P1 of the exchange element 511 is configured to be positioned below the blowout surface F1 where the blowout port that supplies the air outside the building to the desired room is opened.

  Each of the side wall portion 508 of the main body case 502 facing the indoor air suction surface F2 of the exhaust passage P2 and the cover plate 515 of the main body case 502 facing the indoor air suction surface F2 has a suction port 516 for indoor air suction, respectively. It is provided so that it can be closed.

  Hereinafter, each part will be described. The main body case 502 is a rectangular parallelepiped box-shaped metal case. One side wall portion 505 in the longitudinal direction of the main body case 502 has an opening portion 506 for exhausting indoor air to the outside of the building, and an opening portion 506 for exhausting indoor air to the outside of the building. An opening 507 on the inlet side is formed. The other side wall portion 508 in the longitudinal direction of the main body case 502 is formed with an opening 509 on the outlet side for introducing outside air that blows air introduced into the main body case 502 into the room. The openings 507 and 509 constitute an opening for introducing the outside air of the main body case 502, and the opening 506 and an opening 534 described later constitute an exhaust air passage for room air in the main body case 502.

  Further, an opening 514 for detaching the holding members 512 and 513 of the heat exchange element 511 is formed on the side of the bottom plate 510 that contacts the ceiling plate 503 of the main body case 502, and a lid that closes the opening 514 An opening 516 on the entrance side for discharging indoor air to the outside of the building is formed in the plate 515. The opening 516 of the cover plate 515 is an opening for sucking room air, and the opening 516 can be closed by screwing with a cover (not shown).

  The lid plate 515 forms a part of the bottom plate portion 510 in order to close the opening 514. The opening 514 is formed smaller than the opening 504 in order to detach the holding members 512 and 513 from the opening 504. The cover plate 515 is attached to the edge of the opening 514 with a hinge (not shown) and can be opened and closed.

  A fixed frame 519 for storing the fan cases 517 and 518 is attached to a portion of the main body case 502 that is separated from the holding members 512 and 513. A partition plate 520 is attached.

  An exhaust port portion of the fan case 517 disposed on the upper portion of the partition plate 520 is fixed to the vertical wall portion 519A of the fixed frame 519, and an opening portion 521 for exhausting indoor air is opened in the vertical wall portion 519A. Yes. An exhaust port portion of the fan case 518 disposed at the lower portion of the partition plate 520 is fixed to the vertical wall portion 519B of the fixed frame 519, and an opening portion 522 for introducing outside air is opened in the vertical wall portion 519B. .

  The vertical wall 519A of the fixed frame 519 is formed with an opening 523 for introducing outside air for introducing air outside the building. The vertical wall 519B of the fixed frame 519 exhausts indoor air to the outside of the building. An opening 524 for exhausting indoor air is formed.

  A centrifugal fan 525 is disposed inside the fan case 517, and a centrifugal fan 526 is disposed inside the fan case 518. Centrifugal fans 525 and 526 are fixed to rotation shafts 527A and 527B of motors 527Ma and 527Mb attached to partition plate 520, respectively. The motors 527Ma and 527Mb are connected to a control board (not shown) and are rotated by power control from the control board. The fan cases 517 and 518 are respectively provided with bell mouths 517A and 518A serving as openings for taking in air.

  A resin plate 528 is provided between the fixed frame 519 and the side wall portion 505 of the main body case 502. Openings 529 and 530 communicating with the openings 506 and 507 are formed in the resin plate 528, and cylindrical duct joints 531 and 532 are in contact with the edges of the openings 529 and 530.

  On the side wall portion 508 side of the main body case 502, an opening portion 509 for supplying the air outside the building taken into the main body case 502 into the room and an opening portion for discharging other indoor air to the outside of the building 534 is formed. A cylindrical duct joint 535 is in contact with the edge of the opening 509, and a duct joint 536 is in contact with the edge of the opening 534. As shown in FIG. 14, the duct joint 536 is connected to the duct 223 and communicates with the suction port 222. The suction port 222 sucks air collected in the washroom, the dressing room, and these rooms. .

  Duct joints 531, 532 are connected to ducts EAD, ODA communicating with the outside of the building. The duct joint 535 is connected to a duct (not shown) extending to the indoor ceiling for supplying new air taken into the main body case 502. The duct joint 535 can be fitted with ducts connected to supply grills 224A and 225A provided on the ceiling or wall surface of the room where ventilation is desired.

  The heat exchange element 511 serving as a heat exchange means exchanges heat between exhaust air discharged from the room to the outside of the building and introduced air introduced from the outside of the building to the room.

  The heat exchange element 511 is sandwiched and held between the holding members 512 and 513.

  The holding member 512 includes a ceiling plate portion 551 that comes into surface contact with the ceiling plate portion 502 </ b> A of the main body case 502, and a partition plate portion 552 that partitions an air flow path to the heat exchange element 511. The edge portion 552A of the partition plate portion 552 holds the chamfered portion of the corner portion of the heat exchange element 511.

  Further, the holding member 512 is formed with a frame portion 554 that houses a box-shaped air guide portion 553 formed on the cover plate 515. Furthermore, an opening 555 for introducing outside air that leads to the opening 509 and the duct joint 535 is formed, and a suction port 553 for sucking indoor air that can communicate with the suction port 553A for sucking indoor air and the duct joint 536 is formed. Has been.

  The holding member 513 includes a ceiling plate portion 562 that is in surface contact with the ceiling plate portion 502 </ b> A of the main body case 502, and a partition plate portion 563 that partitions an air flow path to the heat exchange element 511. The holding member 513 has an opening 566 for introducing outside air for allowing air to pass through the fan case 518.

  Mounting frames 582 and 583 of filters 580 and 581 for preventing fine dust from entering the passage P of the heat exchange element 511 are detachably supported on the upper surface of the cover plate 515.

  A front panel 588 for introducing indoor air into the opening 516 of the cover plate 515 is detachably attached to the lower side of the cover plate 515. The front panel 588 has an opening 589 for taking in air, and a passage 590 through which air passes is formed between the front panel 588 and the lid plate 515.

  In the ventilator 501 of this embodiment, the outside air introduction air path AR1 for taking in air outside the building into the room includes a duct joint 532, an opening 507 in the vertical wall 505, an opening 530 in the resin plate 528, The opening 523, the arrangement space SP1 (outside air introduction chamber) of the fan case 518 partitioned by the partition plate 520, the fan case 518, the opening 522, the opening 566, and the partition plate 563 are partitioned. A space SP2 below the holding member 513, a filter 580, a heat exchange element 511, a space SP3 above the partition plate portion 552 of the heat exchange element 511 and the holding member 512, an opening 509, and a duct joint 535 are formed. Is done.

  The ventilation air path AR2 for discharging indoor air to the outside of the building includes an opening 589 of the front panel 588, a passage 590 between the front panel 588 and the cover plate 515, an opening 516, and a heat exchange element 511. And a space SP4 below the partition plate portion 552 of the holding member 512, a space SP5 above the partition plate portion 563 of the heat exchange element 511 and the holding member 513, an opening 564, an opening 524, and a space above the partition plate 520. SP6 (indoor air introduction chamber), a fan case 517, openings 521, 529, and 506 and a duct joint 531 are included.

  FIG. 14 shows a case where the ventilation device 501 shown in FIG. 13 is installed on the ceiling of the passage 220, and the indoor air inlet 222 is provided on the ceiling of the washroom / dressing room 221. The indoor air inlet 222 is connected to the duct joint 536 through the duct 223. The damp indoor air in the washroom / dressing room 221 is sucked from the indoor air inlet 222 and exhausted to the outside of the building. The kitchen K is provided with a range hood fan 600 that exhausts the air in the kitchen K.

  203A is a hood for taking outside air into the building, and 203B is a hood for discharging indoor air to the outside of the building. An outside air inlet (not shown) provided near the hood 203A is connected to a duct joint 532 of the ventilation device 501 via a duct, and an exhaust port (not shown) provided near the hood 203B is connected via a duct. It is connected to the duct joint 531 of the ventilation device 501.

  Three duct joints 535 of the ventilator 501 are provided, and the air supply ports 224A provided at the corners of the Japanese-style room 224 and the air supply ports 225A and 225B provided at the corners of the dining living room 225 are respectively connected via ducts. It is connected to the duct joint 535, and external air is supplied from these air supply ports 224A, 225A, 225B. Air is supplied from the air inlets 224A, 225A, 225B of the Japanese-style room 224 and the dining living room 225, and the supplied air is the door 226 and the entrance / exit 227 of the Japanese-style room 224 located diagonally away from the air-supplying openings 224A, 225A. Through the undercut part and the louver part provided in the lower part of the air, it is collected and sucked into the opening part 516 and the suction port 222 provided in the ventilation device 501. For this reason, since indoor space is used as a ventilation path, ventilation can be performed without stagnation.

  FIG. 15 conceptually shows the ventilation system of the third embodiment. In this ventilation system, when the range hood fan 600 is not operating, the motors 527Ma and 527Mb (see FIG. 13) of the ventilation device 501 are driven with a normal driving force, and the centrifugal fans 525 and 527Mb are driven by the motors 527Ma and 527Mb. 526 rotates.

  By the rotation of the centrifugal fan 526, outside air OA is sucked from the outside air suction port of the hood 203A shown in FIG. 14, and is blown to the heat exchange element 511 through the outside air introduction air path AR1. Further, the air OA is blown to the opening 555 and the duct joint 535 through the outside air passage P1 of the heat exchange element 511. The outside air blown to the duct joint 535 is sent as SA to the air supply ports 224A, 225A, 225B through the duct, and the outside air SA is supplied from the air supply ports 224A, 225A, 225B to the Japanese-style room 224 and the dining living room 225. The

  On the other hand, the rotation of the centrifugal fan 525 sucks indoor air RA through the opening 589 of the front panel 588, and the sucked indoor air RA is sucked in the direction of the arrow shown in FIG. The exhaust gas passes through the exhaust passage P2, and further passes through the exhaust air path AR2, and is exhausted from the exhaust port of the hood 203B as exhaust EA.

  When the range hood fan 600 is not operating, the air volume RA of the indoor air sucked into the opening 589 of the front panel 588 and the air volume exhausted from the exhaust port of the hood 203B through the duct joint 531 and the duct. The EA, the air volume OA of the outside air sucked from the outside air inlet of the hood 203A, and the air volume SA of the outside air supplied into the room from the air inlets 224A, 225A, 225B through the duct joint 535 and the duct are equal to each other. ing. That is, RA = EA = OA = SA.

  In other words, the amount of air supplied into the room is equal to the amount of air exhausted out of the room and is balanced, and the room does not become negative pressure.

  When the range hood fan 600 is operated, the total exhaust amount of the exhaust amount by the ventilator 501 and the exhaust amount by the range hood fan 600 becomes larger than the air supply amount by the ventilator 501.

  However, the driving force of the motor 527Ma of the ventilation device 501 is reduced, and the rotational speed of the centrifugal fan 525 is reduced. Further, the driving force of the motor 527Mb is increased, and the rotational speed of the centrifugal fan 526 is increased. Thereby, the air supply amount (SA, OA) into the room by the ventilator 501 increases and the exhaust amount (RA, EA) decreases.

  For this reason, even if the range hood fan 600 operates, the total exhaust amount of the exhaust amount of the ventilator 501 and the exhaust amount of the range hood fan 600 is prevented from being larger than the supply amount of the ventilator 501. The That is, even if the range hood fan 600 is operated, the exhaust amount of the ventilator 501 is reduced, and the air supply amount of the ventilator 501 is increased, so that the room is balanced. In other words, the motors 527Ma and 527Mb of the ventilator 501 are controlled so that the balance between the air supply amount of the ventilator 501 and the exhaust amount of the ventilator 501 and the total exhaust amount of the range hood fan 600 is not lost.

  In addition, while operating the range hood 300, by reducing the rotational speed of the centrifugal fan 525, the exhaust air volume by the ventilation device 501 is reduced and the rotational speed of the centrifugal fan 526 is increased to increase the supply air volume. If the balance between the air supply amount and the exhaust amount is equal in the house, the exhaust air amount by the ventilator 501 is reduced by reducing the rotational speed of the centrifugal fan 525, and the centrifugal fan 526 The air supply air volume may be maintained without changing the rotation speed.

  This control prevents negative pressure inside the house, prevents heavy opening and closing of doors and windows, and prevents inflow of air from the natural air inlet into the room. No wind noise is generated.

  The ventilation system according to the third embodiment performs continuous ventilation that continuously or intermittently ventilates, and satisfies the predetermined (regulated) ventilation volume of the area that needs ventilation in the entire house. . The predetermined ventilation volume is the same as that of the first embodiment, and the same effect as that of the first embodiment can be obtained.

  In the ventilation system of the third embodiment, when the range hood fan 600 is operated, the motors 527Ma and 527Mb are controlled. As in the second embodiment, the air volume detection devices 101 and 110 are provided, Changes in the supply air volume and the exhaust air volume of the ventilator 501 are detected by the outside wind pressure, and when these fluctuations are large, processing similar to step 11 shown in FIG.

  That is, for example, when the outside air supply amount SA increases due to the outside air pressure (outside wind pressure) and the exhaust amount EA decreases, the driving force of the motor 527Mb with the increased air supply amount is reduced to define the air supply amount SA. Use air supply. Further, it is determined that the load of the motor 527Ma having the reduced exhaust amount EA has increased, and the driving force of the motor 527Ma is also reduced.

  Conversely, when the air supply amount SA decreases and the exhaust amount EA increases, the driving force of the motor 527Ma is reduced and the driving force of the motor 527Mb is reduced so that the exhaust amount becomes the specified exhaust amount.

  As described above, if the driving force of the motors 527Ma and 527Mb of the ventilation device 501 is reduced so that one of the airflows satisfies the specified airflow, and the driving force of the motors 527Ma and 527Mb having increased load is reduced, The same effect as in the second embodiment can be obtained.

  Note that the driving force of both the motor 527Mb and the motor 527Ma was reduced when the environment such as the external wind pressure changed. However, if one of the air supply amount and the exhaust amount is controlled to be the specified air amount, the motor 527Mb Alternatively, the driving force of only one of the motors 527Ma may be adjusted.

  In the third embodiment, the indoor air suction port of the ventilation device 501 is the opening 589 provided on the lower surface of the main body and the indoor air suction port 222 provided on the ceiling of the washroom / dressing room 221. The suction port 222 may be installed on the ceiling or wall surface of the room other than the washroom / dressing room, and without the duct joint 536 of the ventilator 501, only the opening 589 provided below the main body. Good. Further, the indoor air suction port 222 of the duct 223 may be provided in a passage such as a corridor, and the indoor air of the house may be sucked without providing the opening 589.

  The number of the air supply ports 224A and 225A is two, but the number of air supply ports 224A and 225A may be three or any other number. A plurality of air may be supplied to a plurality of rooms.

It is explanatory drawing which showed the structure of the ventilation system which concerns on this invention. It is sectional drawing which showed the structure of the bathroom air conditioner. It is the bottom view which deleted a part of bathroom air conditioner. It is the bottom view which showed the intermediate | middle duct fan. It is the side view which showed the intermediate | middle duct fan. It is explanatory drawing which showed the range hood fan. It is the block diagram which showed the structure of the control system of a ventilation system. It is the flowchart which showed operation | movement of the ventilation system. It is explanatory drawing which showed the ventilation system notionally. It is the block diagram which showed the structure of the control system of the ventilation system of 2nd Example. It is explanatory drawing which showed notionally the ventilation system of 2nd Example. It is the flowchart which showed the operation | movement of 2nd Example. It is sectional drawing which showed the structure of the ventilation apparatus of 3rd Example. It is explanatory drawing which showed the ventilation system of 3rd Example. It is the conceptual diagram which showed schematically the ventilation system of 3rd Example.

Explanation of symbols

10 Bathroom air conditioner (ventilating means)
40 Intermediate duct fan (air supply means)
70 range hood fan

Claims (4)

An air supply means for supplying outside air into the building, a bathroom air conditioner that is provided in the bathroom in the building and exhausts the air in the bathroom to the outside, and controls the air conditioning in the building; A ventilation system provided with a range hood fan provided in the kitchen and exhausting the air of the kitchen to the outside,
When the range hood fan starts operating with the air supply means and the bathroom air conditioner operating,
The bathroom air conditioner captures an operation start signal from the range hood fan, and reduces the exhaust amount by the bathroom air conditioner, whereby the air supply amount by the air supply means, the exhaust amount by the range hood fan, and The ventilation system characterized by performing control so that the total displacement of the displacement by the said bathroom air conditioner becomes equal. The ventilation system according to claim 1 , wherein the bathroom air conditioner is a device separate from the air supply unit, and controls the air supply unit in conjunction with the operation of the bathroom air conditioner . The ventilation system according to claim 1 or 2, further comprising heat exchange means for exchanging heat between outside air and indoor exhaust air . A residential structure comprising the ventilation system according to any one of claims 1 to 3.

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