JP3472254B2 - Air barrier ventilation system and blower for the system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air barrier ventilation system for providing an air barrier in the room near the window by ventilating the air in the room near the window facing the outdoors, and a blower for the system. Is.

[0002]

2. Description of the Related Art In such a conventional system, as shown in FIG. 8, an air barrier box 3 is provided under a room 2 near a window 1 facing the outside, and the air barrier box 3 is provided. An air intake port 3a provided in the lower end of the front side surface of the air barrier box 3 in which a blower 5 (so-called fan coil unit) configured by an air conditioning coil 4 and a normal sirocco fan is housed in the box 3 The indoor air sucked from the air barrier box 3 has a structure in which it is blown upward along a window 1 as shown by an arrow in the drawing from a slit-shaped blower port 3b provided on the upper surface.

However, in the above-mentioned conventional system, since the intake port 3a is located at the lower end of the front side surface of the air barrier box 3, dust around the floor surface 6 is sucked, so that the blower 5 is maintained. However, there is a problem that cleaning and maintenance therefor requires much labor and cost. Further, in the above conventional system, the air outlet on the upper surface of the air barrier box 3
The problem is that cold draft (cold air) near the window 1 cannot be sucked into the lower part of the room 2 in winter because only upward airflow from 3b is possible, which makes it difficult to effectively reduce the effect of cold radiation. There was also. Further, in the above-mentioned conventional system, it is necessary to dispose a large air barrier box 3 near the window, so that there is a problem that a large space is required near the window and design restrictions are increased. There is also a problem that the operating sound and vibration of the device 5 are transmitted to the air barrier box 3 and the air barrier box 3 becomes a noise source, and the noise is annoying in a quiet office.

[0004]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an air barrier ventilation system and an air blower for the system, which can advantageously solve the above problems. The air barrier ventilation system according to the present invention described in 1 is an air barrier ventilation system for ventilating the air in a room near a window facing the outside, and is arranged at a lower part of the room near the window and apart from the floor and the window. An air blower extending along the window, and an upper air intake device that sucks in air in the upper part of the room near the window and discharges the air outdoors or returns it indoors after an air conditioning process, One in which the blower device extends downwardly along the extending direction of the blower device, and downwardly extending intake ports and obliquely upward blower ports facing the window and horizontally along the window; Or a plurality of cross-flow blowers, and the air in the room near the window sucked from the intake port by the cross-flow blower is applied obliquely upward from the blow port to the window, and along the window upwards. It is characterized by being sent out.

In such a system, the system is arranged in the lower part of the room near the window facing the outside, spaced apart from the floor surface and the window and extending along the window, and along each of the extending directions. A blower device having a downward air inlet that extends downward and an obliquely upward air outlet that faces the window, and one or more cross-flow fans that extend horizontally along the window, near the window that is sucked in from the air inlet by the cross-flow fan. The air in the room is applied diagonally upward from the air outlet to the window and sent upward along the window, and the upper air intake device, which has an air inlet in the ceiling, sucks in the air in the upper part of the room near the window. The air is ventilated by the window by discharging the air outdoors or returning it indoors after air conditioning. Moreover, since the blower has one or more cross-flow blowers that horizontally extend along the window, in principle, the air is sucked in widely and blows the air widely, so that the air is blown along the window more efficiently. Can be sent.

Therefore, according to the system of the present invention, especially in the summer, the hot air at the window facing the outdoors is sent upward by the air blower, and is sucked by the upper air intake and discharged to the outside, or air conditioning. Since it can be returned to the room after processing, it can keep the room cool and comfortable, and since it does not suck dust near the floor surface, it is troublesome and costly to maintain and maintain the blower. And can be reduced. Further, according to the system of the present invention, it is not necessary to dispose a large air barrier box at the window, so that the space at the window can be effectively used, and free design with less design restrictions can be made possible. .

The air barrier ventilation system according to a second aspect of the present invention is an air barrier ventilation system for ventilating indoor air in the vicinity of a window facing the outside, wherein the indoor air or the indoor air after air conditioning treatment. And an air supply device for feeding downward from an upper part of the room near the window along the window, and a lower part of the room near the window spaced apart from the floor surface and the window and extending along the window. And a lower side intake device that sucks in the air sent under the floor by the blower device, discharges the air to the outside, or returns to the indoor after air conditioning processing, the blower device, An obliquely upward air intake port and a downward air flow port facing the window, each of which extends along the direction in which the air blower extends, and one or a plurality of cross-flow fans horizontally extending along the window. And the sucking from the suction port of the air which has flowed downward along the windows fed by the air supply device obliquely downward by the cross-flow fan,
It is characterized in that the air is blown out from the blower port to under the floor of the room.

In such a system, the air supply device is
The indoor air near the window facing the outside or the indoor air after air conditioning is sent downward along the window from the upper part of the room near the window, and from the floor and window to the lower part of the room near the window. One or a plurality of them that are spaced apart and extend along the window, and that extend diagonally upward along the direction of extension and the air outlets that face downward and the air outlet downward and horizontally along the window. A blower having a cross-flow blower, and the air blown out by the air supply device and flowing downward along the window is sucked obliquely downward by the cross-flow blower from the intake port and sent out from the blower port to the floor below the room. Ventilation of the air near the window is performed in a process in which the side air intake device sucks the air sent under the floor and discharges it to the outdoors or returns it to the room after air conditioning.
Moreover, since the blower has one or more cross-flow blowers that horizontally extend along the window, in principle, the air is sucked in widely and blows the air widely, so that the air is blown along the window more efficiently. Can inhale.

Therefore, according to the system of the present invention, the cold draft (cold air) at the window facing the outside, especially in winter.
In combination with its own tendency to descend, it is driven downward by air moving downward from the upper part of the vicinity of the window, sucked by the air blower at the lower part of the room and sent out to the underfloor. It can be sucked in and discharged outdoors, or it can be returned to the room after air conditioning, so the effect of cold radiation can be effectively reduced, and the air blower may suck dust near the floor. Since it is not provided, it is possible to reduce the labor and cost for cleaning and maintenance for maintaining the blower. Also, according to the system of the present invention, since it is not necessary to dispose a large air barrier box at the window, it is possible to effectively use the space at the window and enable free design with less design restrictions.

In the system of the present invention, as described in claim 3, the window is provided near the window at a position closer to the indoor side than the obliquely upward blower port or intake port of the blower. A blind that can be moved up and down along the window may be provided.According to such a configuration, the space near the window is partitioned by the blind, and the blower port or the intake port of the blower device that is obliquely upward is located closer to the window than the blind. Since it is located, ventilation can be performed more efficiently, and the effect of heat radiation in summer and cold radiation in winter on the air in the room can be further reduced by the blinds.

Further, in the system of the present invention, as described in claim 4, the air blower is connected to a lower end portion of the blind, and when the blind is lowered, the air blower is separated from a floor surface below the window. The air blower may be placed near the ceiling when the blinds can be raised because there is no influence of heat radiation or cold radiation from the window. You can leave it and use the space by the window effectively at that time.

Here, when the arrangement of the air blower at the use position is interlocked with the lowering of the brand as described above, the operation of the air blower is also interlocked with the lowering of the brand, and the air is blown automatically by the lowering of the brand. The device may be activated, which may obviate the need for complicated control in the central monitoring panel of the building, and may control the operation of the blower device more finely according to the demands of people in the room. can do.

Further, in the system of the present invention,
As described in claim 5, the upper intake device or the air supply device may further include another blower device that is disposed in an upper part of the room near the window and extends along the window. Well, according to such a configuration, since the blower device discharges the air in the upper part of the room near the window to the outside, sends it to the air conditioner, or sends it downward along the window, it sucks air into the ceiling of the room. It is possible to ventilate the air near the window more efficiently than in the case where the mouth and the air supply port are provided.

[0014]

Further, in the system of the present invention, as described in claim 6, the blower device extends horizontally along the window and is obliquely upwardly arranged along the extending direction. A housing having a ventilation port and a downward ventilation port, and is housed in the housing so as to extend along the extending direction of the housing and supported by the housing so as to be rotatable about a horizontal axis. And one or more of the cross-flow blower, wherein the cross-flow blower rotates the inside of the housing to make the obliquely upward ventilation port the ventilation port and the downward ventilation port to the suction port. And a position where the obliquely upward vent is used as the intake port and the downward vent is used as the blower port may be selectively disposed. According to such a configuration, one blower can be made to blow air along the window and suck air along the window in correspondence with both summer and winter. The cost required for the harmony facility can be reduced, and the space efficiency in the room can be improved.

Further, in the system of the present invention, as described in claim 7, the blower device extends horizontally along the window and is obliquely upwardly arranged along the extending direction. And a one or more cross-flow fans housed in the housing so as to extend along the extending direction of the housing, and the cross-flow blower. But,
A bearing that rotatably supports one end of the fan rotor shaft and a motor that rotatably drives the other end of the fan rotor shaft are respectively provided through a vibration absorbing member, and the housing supports the casing. The fan rotor of the once-through fan and the motor for driving the fan rotor of the cross-flow fan are
Since the casings supported by the housing are all supported through the vibration absorbing member, when the cross flow fan is operated,
Vibrations due to the imbalance of the rotor of the fan rotor and the motor, vibrations due to the alignment error between the motor shaft and the fan rotor shaft, and electromagnetic vibrations of the motor are transmitted from the fan rotor and the motor to the casing inside the housing. Can be effectively prevented, and noise during operation of the cross-flow fan can be reduced. Therefore, according to this system, the operating noise and vibration of the blower can be reduced, and the operating noise of the blower can be avoided even in a quiet office.

In the system of the present invention, as described in claim 8, the housing may support the casing via a vibration absorbing member. According to this structure, when the cross flow fan is operated, Even if some vibration is transmitted from the fan rotor or motor to the casing, it is possible to effectively prevent the vibration from being transmitted from the casing to the housing, and it is possible to further reduce the noise during operation of the cross-flow blower, and in turn the blower. The operating noise of can be made quieter.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will now be described in detail with reference to the drawings by way of examples. 1 is a cross-sectional view showing a first embodiment of the air barrier ventilation system of the present invention, and FIG. 2 is a plan view of the system of the embodiment, in which reference numeral 1 faces the outside. window,
2 is a room, 2a is a partition (partition), 6 is a floor, 7 is a ceiling, and 8 is a ceiling 7 on both sides of the partition 2a.
The blinds that can be moved up and down are mounted on the screen.

In the air barrier ventilation system of the first embodiment, as shown in FIGS. 1 and 2, for each room 2, there is a window 1 below the blind 8 under the room 2 near the window 1 facing the outdoors. Two blowers 9 are provided near the window 6 and are spaced apart from the floor 6 by about 30 cm so as to be aligned with each other in the longitudinal direction. It comprises a duct 10 having a portion 10a extending to the back side of the ceiling 7 and an air conditioner (not shown) connected to the other end of the duct 10, where the lower part of the room 2 near the window 1 is provided. Is a column 12a that is erected on the structural material 11 inside the building, and a general inverted pedestal that extends along the window 1 at a position that is fixed to the upper end of the column 12a and is separated from the floor surface 6. A support member 12 having a horizontal cross member 12b having a cross-sectional shape is provided. Each of the two blowers 9 is fixed on the horizontal member 12b of the supporting member 12 thereof, and
It extends almost horizontally along.

Further, each air blower 9 as one embodiment of the air blower of the present invention in the first embodiment is shown in FIG.
As shown in FIG. 4 and FIG. 4, a substantially cylindrical housing 13 having a lower end fixed on the horizontal member 12b, and a blind receiver 14 that protrudes substantially horizontally from the housing 13 toward the indoor side.
And three through-flow blowers 15 in the illustrated example housed in the housing 13 so as to extend along the housing 13.
The housing 13 has an upper half portion that can be opened and closed, and is arranged obliquely downward at the positions of the cross flow fans 15 along the extending direction of the housing 13. It has an intake port 13a and a blower port 13b that is obliquely upward.

Here, each of the three cross-flow fans 15 has a fan rotor 15a, a motor 15b for rotationally driving the shaft of the fan rotor 15a, as in the known cross-flow fans.
The fan rotor 15a has a casing 15c that surrounds the upper half of the fan rotor 15a and supports the fan rotor 15a and the motor 15b. In particular, in this embodiment, the left end of the shaft of the fan rotor 15a in FIG. Figure 3 of 15c
Is rotatably supported by a bearing (not shown) built in a synthetic rubber housing 15d as a vibration absorbing member fixed to the left end, and both ends of the motor 15b are fitted to the right end in FIG. 3 of the casing 15c. Is supported by a synthetic rubber cap 15e as a vibration absorbing member, and the output shaft of the motor 15b is at the right end portion of the shaft of the fan rotor 15a in FIG. The fan rotor 15a and the motor 15b are connected by a coupling.
The casing 15c is supported only by the vibration absorbing member.

Further, in the first embodiment, the brackets 15f having U-shaped cross-sections, which project from both ends of the casing 15c and extend in the direction away from each other, also include two synthetic rubber inserts serving as vibration absorbing members. It is sandwiched from above and below by the plate 15g, and is attached to the bottom of the above-mentioned roughly cylindrical housing 13 by bolts 15h loosely inserted into the insertion plate 15g and the bracket 15f, whereby the casing 15c is
Substantially only the vibration absorbing member supports the housing 13.

In the system of the first embodiment,
An air blower 9 which is arranged below the floor 6 in the lower part of the room 2 near the window 1 facing the outside and extends along the window 1.
Has an obliquely downward intake port 13a and an obliquely upward blower port 13b respectively arranged along the extending direction thereof,
As shown by the broken line arrow in FIG. 1, the air in the room 2 near the window 1 that has been widely sucked from the air inlet 13a is blown into the air outlet 13a.
Send it upward from b along the window 1. And
The opening 10a of the duct 10 that constitutes the upper intake device is the window 1
Inhale the air above the room 2 nearby,
This is also sent to the air conditioner that constitutes the upper air intake device, and the air conditioner appropriately air-conditions the air and then returns the air to the room 2. Ventilation is performed.

Therefore, according to the system of the first embodiment, especially in the summer, the hot air at the window of the window 1 facing the outside is sent upward by the air blower 9 and is sucked by the upper air intake device to suck the air. Since it can be returned to the room 2 after the harmony treatment, the room 2 can be kept cool and comfortable, and since dust around the floor surface 6 is not sucked, cleaning and maintenance for maintaining the blower 9 can be performed. The labor and cost of maintenance can be reduced. In addition, since it is not necessary to dispose a large air barrier box near the window, it is possible to effectively use the space near the window and enable a free design with few design restrictions.

Further, according to the system of the first embodiment, the air blower port 13b in the vicinity of the window 1 and directed obliquely upward of the air blower 9 is provided.
A blind 8 that can be moved up and down along the window 1 is provided at a position closer to the room 2 than the room 2, and the blind 8 partitions the space near the window 1 from the space closer to the room 2 than the blind 8. Also, since the blower port 13b of the blower device 9 which is diagonally upward is located facing the space near the window 1, it is possible to perform the ventilation at the window more efficiently, and the blinds 8 for the air in the room 2 It is possible to further reduce the effects of heat radiation in summer and cold radiation in winter.

According to the system of the first embodiment, the blower 9 is equipped with the cross-flow blower 15. The cross-flow blower 15 sucks air widely and blows the air broadly. The air can be efficiently sent along the window 1, and the fan rotor of the once-through blower 15 can be efficiently supplied.
15a and the motor 15b that drives it in rotation
A casing 15c supported by 13 includes a synthetic rubber housing 15d and a synthetic rubber cap 15 as vibration absorbing members.
and the output shaft of the motor 15b is connected to the end portion of the shaft of the fan rotor 15a by an elastic coupling with a synthetic rubber member as a vibration absorbing member interposed. When the blower 15 is operating, vibrations due to the imbalance of the rotor of the fan rotor 15a and the motor 15b, vibrations due to the alignment error between the motor shaft and the fan rotor shaft, and vibrations such as electromagnetic vibrations of the motor 15b are generated. 15a or motor 15b to housing 13
It is possible to effectively prevent the noise from being transmitted to the inner casing 15c, and it is possible to reduce noise during operation of the cross-flow fan 15.

In addition, the housing 13 has a casing 15c.
Is supported via two synthetic rubber insert plates 15g as vibration absorbing members, so some vibration may occur during operation of the cross flow fan 15 from the fan rotor 15a and the motor 15b to the casing 15c.
Even when it is transmitted to the housing 13, the vibration can be effectively prevented from being transmitted from the casing 15c to the housing 13, and the noise during operation of the cross-flow fan 15 can be further reduced. Therefore, according to the system of the first embodiment, the operating noise and vibration of the blower 9 can be reduced, and the operating noise of the blower 9 can be suppressed even in a quiet office.

FIGS. 5 (a) and 5 (b) are sectional views showing a second embodiment of the air barrier ventilation system of the present invention in different operating states, respectively, and in the figure, portions similar to those of the previous embodiment. Are indicated by the same reference numerals.

That is, the system of the second embodiment is
As shown in FIGS. 5 (a) and 5 (b), each room 2 is connected to a lower end of a blind 8 provided on a ceiling 7 of the room 2 near the window 1 facing the outdoors so as to be able to move up and down. As shown in FIG. 5 (a), the blind 8 is provided with a blower 9 arranged at a position separated by about 30 cm from the floor 6 as shown in FIG. 2 has an opening 10a at one end on the ceiling 7
The air conditioner (not shown) connected to the duct 10 extending to the back side of the duct 10 and the other end of the duct 10 is provided. Here, the blind 8 is a wall surface extending parallel to the paper surface in FIG. The guide rail (not shown) provided in the upper part guides the ascending / descending operation, whereby the blower 9 is also maintained at the predetermined position in the lowered state of the blind 8. The blower device 9 has substantially the same structure as that of the first embodiment, and the blower port 13b of the housing 13 thereof.
Is located diagonally upward toward the space closer to the window 1 than the blind 8. Further, the blower device 9 is wired so that the blower operation is started when the blind 8 is lowered, and the blower operation is stopped when the blind 8 is raised.

In the system of the second embodiment,
When the blind 8 is moved down, the air blower 9 moves downward under the guidance of the guide rails and starts the air blowing operation in conjunction with the operation of the blind 8, and in the lowered state of the blind 8 shown in FIG. As shown in the first embodiment, as in the first embodiment, the air in the room 2 near the window 1 sucked wide from the obliquely downward intake port arranged along the extending direction of the blower 9 is also changed. The air is blown upward in a wide manner along the window 1 from an obliquely upward blower port arranged along the extending direction of the blower 9. The opening 10a of the duct 10 constituting the upper intake device sucks in the air in the upper part of the room 2 near the window 1 and sends the air to the air conditioner which also constitutes the upper intake device. The air conditioner appropriately returns the air to the room 2 after air conditioning.
In this process, air is ventilated near the window of the window 1 facing the outside. Therefore, it is possible to obtain the same effect as that of the first embodiment.

On the other hand, when the blind 8 is moved up, the air blower 9 moves up under the guidance of the guide rails and the air blow operation is stopped in conjunction with the operation of the blind 8, and when the blind 8 is raised and stored as shown in FIG. 5 (b). The blower 9 is also pulled up to the position of the ceiling 7.

Therefore, according to the system of the second embodiment, since there is no influence of heat radiation or cold radiation from the window, the blower 9 is also retracted near the ceiling when the blind 8 can be raised. It is possible to store it, and at that time, the space by the window can be effectively used. Moreover, since the operation of the blind 8 and the blower 9 are interlocked with each other, complicated control at the central monitoring panel of the building can be eliminated, and the blower 9 can be operated more finely according to the request of the person in the room. Can be controlled.

FIGS. 6 (a) and 6 (b) are sectional views showing the third embodiment of the air barrier ventilation system of the present invention in different operating states, respectively, and in the figure, the same parts as the previous embodiment are shown. Are indicated by the same reference numerals.

That is, the system of the third embodiment is
It is connected to the duct 10 extending to the back side of the ceiling 7 and the other end of the duct 10 having an opening 10a at one end in the upper part of the room 2 near the window 1 and serving as both the upper intake device and the air supply device. It is equipped with an air conditioner (not shown), and is arranged in the lower part of the room 2 near the window 1 closer to the window 1 than the blind 8 and spaced about 30 cm from the floor surface 6 so as to be aligned with each other in the longitudinal direction. Further, as a lower air intake device, it was provided with an air blower 9 of a table, and was connected to an underfloor space extending to the back side of the floor 6 with an opening 6a in the floor 6 at the bottom of the room 2 near the window 1. , Equipped with an air conditioner (not shown).

In the system of the third embodiment, however, each air blower 9 as another embodiment of the air blower of the present invention has a substantially cylindrical housing 13 as in the previous embodiment. The housing 13 is provided with a plurality of once-through blowers 15 (here also three for each housing 13) accommodated so as to extend along the extending direction of the housing, and the housing 13 is provided in the window 1. Although extending substantially horizontally along the housing 13, the housing 13 has an obliquely upward ventilation port 13c and an obliquely downward ventilation port 13d, which are arranged along the extending direction. A plurality of cross-flow blowers 15 housed in, is supported by the housing 13 rotatably around an axis extending in the extending direction of the housing 13, all of the cross-flow blowers 15,
By operating a lever (not shown), the housing 13 is integrally rotated around the above-mentioned axis, and the obliquely upward vent 13c shown in FIG. 6 (a) is used as a blower and the oblique downward vent 13d is taken in. It is selectively arranged at the position where the mouth is opened and the position where the obliquely upward ventilation port 13c is used as the intake port and the obliquely downward ventilation port 13d is used as the ventilation port, as shown in FIG. 6B.

In the system of the third embodiment,
For example, in the summer, as shown in FIG.
Operate all the cross-flow blowers 15 inside by operating the levers so that the diagonally upward vents 13c are used as the vents and the diagonal downward vents 13d are used as the intake ports, and the upper intake device is operated. When the constituent air conditioner is operated, like the first embodiment, the blower device 9 is arranged below the floor 6 in the lower part of the room 2 near the window 1 and extends along the window 1. However, as shown by the broken line arrow in FIG. 6 (a), the air in the room 2 near the window 1 that has been widely sucked from the diagonally downward ventilation port 13d, which is the intake port, is the upward ventilation port, which is the ventilation port. Along the window 1 from 13c, it is sent out wide above the window space that can be partitioned by the blind 8.
The opening 10a of the duct 10 that constitutes the upper intake device
Sucks the air in the upper part of the room 2 near the window 1 and sends the air to the air conditioner which also constitutes the upper air intake device, and after the air conditioner appropriately air-conditions the air. In the process of returning to the room 2, the air is ventilated near the window of the window 1 facing the outside.

Further, for example, in winter, as shown in FIG. 6 (b), all the through-flow blowers 15 in the housing 13 are operated by operating the levers so that the diagonally upward vents 13c serve as the intake ports and the diagonally downward vents. When the air vent 13d is placed at a position where it serves as a ventilation port and operated, and when the air conditioner that constitutes the air supply device and the air conditioner that constitutes the lower intake device are actuated, the broken line in FIG. As indicated by the arrow, the duct 10 on the back side of the ceiling 7 is connected to the air conditioner that constitutes the air supply device.
The warm air after the air conditioning process that is supplied to the air and sent out along the window 1 from the upper opening 10a of the room 2 near the window 1 forcibly lowers the air in the window space that can be partitioned by the blind 8. Further, a blower 9 which is arranged below the floor 6 in the lower part of the room 2 near the window 1 and extends along the window 1 draws in a wide air from an obliquely upward vent 13c which is an intake. The air in the room 2 near the window 1 is blown out wide from the diagonally downward ventilation port 13d which is used as a ventilation port.
It is sent to the underfloor space on the back side of the floor surface 6 through the opening 6a of the floor surface 6 in the lower part of the room 2 near the window 1. Then, the air conditioner that constitutes the lower side air intake device sucks the air sent to the underfloor space, appropriately air-conditions it, and then returns it to the room 2 in the process of opening the window 1 facing the outside. Ventilation of air is performed.

Therefore, according to the system of the third embodiment, as in the case of the first embodiment, particularly in summer, the hot air at the window of the window 1 facing the outside is sent upward by the blower 9. Since it can be returned to the room 2 after being sucked in by the upper air intake device and subjected to the air conditioning process, the room 2 can be kept cool and comfortable, and dust around the floor surface 6 will not be sucked in. It is possible to reduce the labor and cost of cleaning and maintenance for maintaining the blower 9.

Further, according to the system of the third embodiment, especially in the winter, the cold draft (cold air) at the window of the window 1 facing the outside is combined with the nature of the window itself to descend. At the same time, the warm air after the air-conditioning process from the upper part near 1 is driven downward, and at the same time, it is sucked by the air blower 9 at the lower part of the room and sent out to the underfloor space, which is an air conditioner that constitutes the lower air intake device. Since the air can be returned to the room 2 after being sucked and subjected to the air conditioning process, the effect of cold radiation can be effectively reduced.

According to the system of the third embodiment, the blind 8 separates the space near the window 1 from the space closer to the room 2 as in the previous two embodiments. Also facing the space near the window 1
Vents 13c diagonally upward as air intake and air blower
Is located, the ventilation at the window can be performed more efficiently, and the blind 8 can further reduce the influence of heat radiation in the summer and cold radiation in the winter on the air in the room 2.

In addition, according to the system of the third embodiment, the once-through blower 15 in the housing 13 of the blower device 9 blows air along the window 1 in correspondence with both summer and winter, Since air can be sucked in along the window 1, the cost required for the air conditioning equipment can be reduced and the space efficiency of the room 2 can be increased.

FIG. 7 is a sectional view showing a modification of the air barrier ventilation system of the third embodiment. In the figure, the same parts as those in the previous embodiment are designated by the same reference numerals. That is, in this modified example, the building has an air passage extending over a plurality of rooms on the same floor by a ceiling 7 near a window, a structural material 11 supporting the ceiling 7, and an outer wall material 16 facing the outside. Which defines an air barrier duct 17, which is connected to an air conditioner (not shown), and the opening 7a is provided in the ceiling 7 near the window,
The upper part of the room 2 near the window 1 and the air barrier duct 17
And are in communication.

The system of this modification is the same as the third system described above.
Similar to the system of the embodiment, it is arranged substantially horizontally below the window 1 along the window 1, and by rotating the once-through blower 15, the two ventilation holes 13c and 13d are provided as the ventilation port and the intake port. In addition to the blower 9 that can be switched to and, as a lower air intake device, an underfloor space that extends behind the floor 6 with an opening 6a in the floor 6 at the bottom of the room 2 near the window 1 is provided. A connected air conditioner (not shown) is provided, and the structural member 11 near the ceiling 7 has the same structure as the blower 9 below the window 1 so as to be located above the room 2 near the window 1. By rotating the cross-flow fan 15 to the two ventilation holes 13c, 13d
Is further provided with another blower device 9 capable of switching between the blower port and the intake port.
Together with the air barrier duct 17 and the air conditioner connected thereto, constitute an upper intake device and an air supply device.

According to the system of this modification, by rotating the once-through blowers 15 in the lower and upper blowers 9 near the window 1, respectively, as in the system of the third embodiment, for example, In the summer, as shown by the arrow A in the figure, air is sent upward so that the heated air near the window of the window 1 facing the outside is air-conditioned and returned to the room 2. For example, in the winter, the arrow in the figure As shown by B, air can be sent downward, and cold draft (cold air) at the window of the window 1 facing the outside can be returned to the room 2 after being subjected to the air conditioning treatment. The same effect can be brought about, and moreover, since the additional air blower 9 is provided especially above the room 2 near the window 1, the air blower 9 air-conditions the air above the room 2 near the window 1. Send to device, along window 1 Since or send downward, it is possible to perform efficient ventilation window side of the air than when using only intake or air supply opening provided in the ceiling 7 of the room 2.

Although the present invention has been described above based on the illustrated example, the present invention is not limited to the above-mentioned example. For example, in the above-described modified example, between the underfloor space and the air barrier duct 17 therebelow, The structural material 11 does not completely divide the space, but makes a partial cut so as to communicate with each other. In winter, a damper that can close the opening 7a of the ceiling 7 is provided, and the air in the air barrier duct 17 is provided. May be constantly sucked by an air conditioner, and in this way, in the winter, the air near the ceiling 7 of the room 2 is sent downward by the air blower 9 at the upper part to generate cold draft (cold air). It can be driven downwards, sucked by the blower 9 at the lower part, sent out into the air barrier duct 17 through the opening 6a of the floor surface 6 and the cut of the structural material 11, and then sent to the air conditioner. ,Sky It is possible to combine the conditioning apparatus, the wirings such as OA (Office Automation) equipment under the floor space can be placed sufficiently large number.

Further, although the blower in the above embodiment sucks air from diagonally below and blows it obliquely upward, the blower may be constructed so as to suck air from directly below and blow it obliquely upward.

[0047]

[Brief description of drawings]

FIG. 1 is the first part of the air barrier ventilation system of the present invention.
It is sectional drawing which shows an Example.

FIG. 2 is a plan view of the system of the first embodiment.

FIG. 3 is a front view showing a configuration of a cross-flow fan in an embodiment of the air blower of the present invention used in the above embodiment.

4A is a cross-sectional view of the air blower of the above-described embodiment as seen from the right direction in FIG. 3, and FIG. 4B is a cross-sectional view of the air blower as seen from the left direction in FIG.

5 (a) and 5 (b) are cross-sectional views showing a second embodiment of the air barrier ventilation system of the present invention in different operating states.

6 (a) and 6 (b) are sectional views respectively showing a third embodiment of the air barrier ventilation system of the present invention in different operating states.

FIG. 7 is a sectional view showing a modification of the system of the third embodiment.

FIG. 8 is a cross-sectional view showing a conventional air barrier ventilation device.

[Explanation of symbols]

1 Windows facing the outdoors 2 indoor 2a Partition (partition) 3 Air barrier box 3a intake port 3b blower 4 coils 5 Blower 6 floor 6a opening 7 ceiling 8 blinds 9 Blower 10 ducts 10a opening 11 Structural material 12 Support member 12a prop 12b Horizontal material 13 housing 13a Inlet 13b Vent 13c Diagonally upward vent 13d diagonally downward vent 14 blind receiver 15 once-through blower 15a fan rotor 15b motor 15c casing 15d synthetic rubber housing 15e synthetic rubber cap 15f bracket 15g insertion plate 15h bolt

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor ▲ Tatsu ▼ 8-21-1, Ginza, Chuo-ku, Tokyo Takenaka Corporation Tokyo Main Store (72) Inventor Tetsuya Sugi 8-21, Ginza, Chuo-ku, Tokyo No. 1 Incorporated Takenaka Corporation Tokyo Main Store (72) Inventor Masahiro Kamei 3-10 Nihonbashi Yokoyamacho, Chuo-ku, Tokyo Nisshinbo Trading Co. (72) Inventor Katsuhiko Nomura Nihonbashi Yokoyama-cho, Chuo-ku, Tokyo 3-10 No. 10 Nisshinbo Trading Co., Ltd. (72) Inventor Takashi Arai 33-1, Higashi Omori, Ohira Town, Okazaki City, Aichi Prefecture Japan Polymer Co., Ltd. Okazaki Plant (72) Inventor, Yuji Hamajima Ohira Town, Okazaki City, Aichi Prefecture Omori 33-1 Japan Polymer Co., Ltd. Okazaki Plant (56) Reference JP 2000-193265 (JP, A) JP 57-55336 (JP, A) JP Flat 10-115021 (JP, A) Unexamined Japanese Patent Publication 8-121815 (JP, A) Actual Open 3-3155 (JP, U) Actual Open 56-99312 (JP, U) Actual Open 2-1-13691 (JP , U) (58) Fields investigated (Int.Cl. ⁷ , DB name) F24F ^7/ 00-9/00

Claims (8)

(57) [Claims] 1. An air barrier ventilation system for ventilating indoor air in the vicinity of a window facing the outside, wherein the air barrier ventilation system is disposed in the lower part of the room in the vicinity of the window and is spaced apart from the floor surface and the window and extends along the window. An air blower that is present and an upper air intake device that sucks in the air in the upper part of the room near the window and discharges the air outdoors or returns it to the room after air conditioning treatment , wherein the air blower device Each along the extension direction of the device
Downwardly extending inlet and diagonally upward facing the window
A blower opening and one or more cross-flow blowers that extend horizontally along the window, and the cross- flow blower
The air in the room near the window that has been sucked in from the intake port is sent to the
Touch the window diagonally upward from the wind vent, and put it along the window.
The air barrier ventilation system is characterized in that it is sent upwards . 2. An air barrier ventilation system for ventilating indoor air in the vicinity of a window facing the outside, wherein the indoor air or the indoor air after air conditioning is passed from the upper part of the indoor space near the window to the window. And an air supply device that sends out downwards, a blower device that is arranged at a lower part of the room near the window apart from the floor surface and the window, and extends along the window, and is sent below the floor by the blower device. It was inhale air, and a lower intake system back indoors after or air conditioning process for discharging the air to the outdoors, a comprises the blower, respectively along the extending direction of the blower
Inlet and downward facing upward toward the window that extends
A blower opening and one or more cross-flow blowers that extend horizontally along the window, and are blown out by the air supply device.
The air flowing downward along the window is flowed through the
Suction from the intake port diagonally downward with a blower
The air barrier ventilation system is characterized in that the air is ventilated from the blower port to under the floor of the room . 3. A blind capable of moving up and down along the window is provided near the window at a position closer to the room than the air outlet or the air inlet of the air blower that is obliquely upward. The air barrier ventilation system according to claim 1 or 2, characterized in that. 4. The blower device is connected to a lower end portion of the blind, and is arranged at a position apart from a lower floor surface near the window due to the lowering of the blind. The air barrier ventilation system according to any one of claims 1 to 3. 5. The upper air intake device or the air supply device further comprises another blower device which is disposed in an upper part of the room near the window and extends along the window. The air barrier ventilation system according to any one of claims 1 to 4. 6. The housing includes a housing that extends horizontally along the window and has obliquely upward vents and downward vents that are arranged along the extending direction, respectively. One or a plurality of the cross flow fans supported by the housing so as to be rotatable about a horizontal axis and accommodated in the housing so as to extend along the extending direction of the housing; The blower is rotated within the housing,
A position where the obliquely upward vent is the blower port and the downward vent is the intake port, and a position where the obliquely upward vent is the intake port and the downward vent port is The air barrier ventilation system according to any one of claims 1 to 5, wherein the air barrier ventilation system is selectively arranged at a position to be the blower opening. 7. The blower includes a housing which extends horizontally along the window and has obliquely upward vents and downward vents which are respectively arranged along the extending direction, One or a plurality of the cross flow fans housed in the housing so as to extend along the extending direction of the housing, and the cross flow fan rotatably supports one end of the fan rotor shaft. 7. A casing that supports the motor and a motor that rotationally drives the other end of the fan rotor shaft via a vibration absorbing member, respectively, and the housing supports the casing. Blower for Air Barrier Ventilation System. 8. The housing supports the casing via a vibration absorbing member.
Blower for the air barrier ventilation system described.