JP2005042955A - Ventilating device and house structure with the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact ventilating device with less pressure loss in an inlet of a flute. <P>SOLUTION: This ventilating device is provided with a ventilating fan 33 for sucking indoor air to discharge it out of a building, an air intake fan 34 for sucking air outside a building to supply it into a room, a humidifying/dehumidifying rotor 15 provided along both of an air passage wherein the indoor air flows and an air passage wherein open air flows to give/take humidity between the indoor air and the open air by rotating itself, and an indoor air heater 31 arranged in the upstream of the humidifying/dehumidifying rotor 15 along a flow of the indoor air to heat the indoor air flowing into the humidifying/dehumidifying rotor 15. The humidifying/dehumidifying rotor 15 is provided inside a case of a ventilating device main body, while titling it. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ventilator that is operated continuously for 24 hours, and a residential structure provided with the ventilator.
[0002]
[Prior art]
In recent years, ventilators that dehumidify and humidify indoor air using a dehumidifying / humidifying rotor are known. In addition to the dehumidifying / humidifying rotor, this ventilator is equipped with a suction fan that sucks indoor air, a suction fan that sucks outside air outside the building, and a room that can heat indoor air sucked by the suction fan upstream of the dehumidifying / humidifying rotor. An air heater and an outside air heater capable of heating the outside air sucked by the suction fan on the upstream side of the dehumidifying / humidifying rotor are provided (see, for example, Patent Document 1 and Patent Document 2).
[0003]
The ventilator does not energize the indoor air heater and the outdoor air heater during ventilation, exhausts the indoor air sucked by the suction fan into the outside air outside the building, and supplies the outside air sucked by the suction fan into the room. I care.
[0004]
When dehumidifying, only the outside air heater is operated, and the indoor air sucked by the suction fan is circulated through the dehumidifying / humidifying rotor into the room, and the outside air sucked by the suction fan is exhausted to the outside air outside the building through the dehumidifying / humidifying rotor. By doing so, the room air is dehumidified by the dehumidifying / humidifying rotor.
[0005]
Furthermore, during humidification, only the indoor air heater is operated to circulate the indoor air sucked by the suction fan through the dehumidifying / humidifying rotor, and the outside air sucked by the suction fan passes into the outside air outside the building through the dehumidifying / humidifying rotor. By exhausting, the room air is humidified by the dehumidifying / humidifying rotor.
[0006]
[Patent Document 1]
Japanese Patent No. 2835695 (page 2-4, Fig. 1-3)
[Patent Document 2]
JP-A-9-126493 (page 2-4, FIG. 1-2)
[0007]
[Problems to be solved by the invention]
However, since the dehumidifying / humidifying rotor is installed horizontally in the above-described conventional technology, indoor air or outside air flows into the honeycomb flute (small hole) formed in the dehumidifying / humidifying rotor from a right angle, and the flute There is a problem that the pressure loss at the inlet is large. If the dehumidifying / humidifying rotor is installed horizontally, the case of the ventilator main body becomes longer in the longitudinal direction, making it difficult to make the ventilator main body compact.
[0008]
In the prior art, the indoor air heater is provided on the upstream side of the dehumidifying / humidifying rotor along the flow of indoor air, and the outdoor air heater is provided on the upstream side of the dehumidifying / humidifying rotor along the flow of outside air. Since these heaters are arranged at appropriate locations without considering the flow characteristics of room air and outside air, there is a problem that room air and outside air cannot be efficiently heated. In addition, if a heater is attached to the entire surface of the dehumidifying / humidifying rotor, indoor air and outside air can be sufficiently heated, but this consumes too much power and wastes energy.
[0009]
A first object of the present invention is to provide a ventilator that has a small pressure loss at the flute inlet and can be made compact, and a housing structure including the ventilator.
[0010]
A second problem of the present invention is to provide a ventilator that can efficiently heat indoor air and outside air and contribute to energy saving, and a housing structure including the ventilator.
[0011]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 sucks room air and exhausts it outside the building, sucks outside air outside the building and supplies it to the room, and supplies the room inside the building. A rotor that performs moisture exchange between the room air and the outside air while rotating, and a rotor that performs total heat exchange and at least dehumidification or humidification in the case of the ventilation device main body. It is characterized by having been installed at an angle.
[0012]
The invention according to claim 2 is an exhaust fan that sucks room air and exhausts it outside the building, an air supply fan that sucks outside air outside the building and supplies it to the room, an air passage through which the room air flows, A rotor that is provided over both of the air passages through which the outside air flows, transfers moisture between the room air and the outside air while rotating, and performs total heat exchange and at least dehumidification or humidification; and the flow of the room air A ventilator provided with an indoor air heater disposed on the upstream side of the rotor and capable of heating the room air flowing into the rotor, wherein the rotor is inclined in a case of the ventilator body It is characterized by having been installed.
[0013]
According to each of the above configurations, since the rotor is installed in an inclined manner in the case of the ventilator body, if indoor air or outside air is allowed to flow horizontally during dehumidification in the case of the ventilator body, the room air or outside air Flows obliquely into the flute of the rotor, and the pressure loss at the flute inlet can be kept small. Moreover, if the rotor is inclined and installed, the length of the ventilator main body in the longitudinal direction can be reduced, and thus the ventilator main body can be made compact.
[0014]
According to a third aspect of the present invention, there is provided an exhaust fan that sucks indoor air and exhausts it outside the building, an air supply fan that sucks air outside the building and supplies the air into the room, the exhaust fan, and the air supply fan Is disposed over both the air passage of the air sucked by the exhaust fan and the air passage of the air sucked by the air supply fan, and in the case of the ventilator main body. A rotor that is installed in a horizontal or inclined state and transfers moisture between the two airs while rotating, and is disposed upstream of the rotor along the flow of each air and flows into the rotor A ventilator comprising a heater capable of heating each air, and is arranged upstream of the heater along the flow of each air, and directs the air sent by each fan to the rotor. Air rectifying member that rectifies It is characterized in that was.
[0015]
According to the above configuration, the air sucked by the exhaust fan or the air sucked by the air supply fan is rectified and sent to the heater by the air rectifying member, so that the pressure loss at the flute inlet can be kept small. it can.
[0016]
Further, most of the air sucked by the exhaust fan or the air sucked by the air supply fan flows along the inner surface of the case of the ventilator body, and the wind speed of the air flowing along the inner surface of the case is fast. According to the above configuration, the air with a high wind speed that flows along the inner surface of the case of the ventilator main body is sent to the rotor as it is without being heated by the heater, and the air with a low wind speed that flows away from the inner surface of the case of the ventilator main body Can be led to the heater.
[0017]
The amount of heat of the heater is set to a constant value, and when air with a high wind speed is applied to the heater, the temperature of the air does not rise sufficiently, so the relative humidity does not decrease and the rotor does not release moisture sufficiently. In the configuration, since air having a low wind speed is rectified by the air rectifying member and then guided to the heater, the temperature of the air is sufficiently increased and the relative humidity is reduced, and the moisture is sufficiently released by the rotor.
[0018]
According to a fourth aspect of the present invention, there is provided an exhaust fan that sucks indoor air and exhausts the air outside the building, an air supply fan that sucks air outside the building and supplies the air into the room, the exhaust fan, and the air supply fan Is disposed over both the air passage of the air sucked by the exhaust fan and the air passage of the air sucked by the air supply fan, and in the case of the ventilator main body. A rotor that is installed in a horizontal or inclined state and transfers moisture between the two airs while rotating, and is disposed upstream of the rotor along the flow of each air and flows into the rotor A ventilation device comprising a heater capable of heating each air, wherein the heater is disposed at a location where most of the air that has been sent by the fans and flows along the inner surface of the case hits. It is a feature.
[0019]
As described above, most of the air sucked by the exhaust fan or the air sucked by the air supply fan flows along the inner surface of the case of the ventilator body. According to the said structure, only the air with a high wind speed which flows along the case inner surface of a ventilator main body can be heated intensively with a heater, As a result, it becomes possible to heat air efficiently.
[0020]
When the air sucked by the exhaust fan is heated as in claim 5, the heater is installed at a location away from the exhaust fan and obliquely with respect to the air flow. When the air sucked in is heated, it is preferable that the air is installed near the air supply fan and obliquely with respect to the air flow.
[0021]
According to a sixth aspect of the present invention, the rotor of the part of the air is disposed at a location downstream of the heater along the rotation direction of the rotor and where a part of the air sent by each fan hits. It is characterized in that a blocking member for blocking the inflow to is provided.
[0022]
Some of the air sucked by the exhaust fan or the air sucked by the air supply fan tries to flow into the rotor immediately after being sucked or sucked, apart from the large amount of air flowing along the inner surface of the case of the ventilator body. There is some air to do. Such a part of the air is not heated by the heater, that is, flows into the rotor without lowering the relative humidity, so that the moisture is absorbed by the rotor. However, when the rotor absorbs moisture, the moisture absorption capacity is lowered, and the original function of absorbing moisture from the air is adversely affected.
[0023]
On the other hand, if the blocking member is provided, air can be prevented from flowing into the rotor without being heated by the heater, so the rotor does not absorb moisture from the air, and the moisture absorption capacity Can be suppressed.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(Embodiment 1)
1 to 5 show a ventilator according to Embodiment 1, FIG. 1 is a longitudinal sectional view thereof, FIG. 2 is a transverse sectional view thereof, and FIG. 3 is a sectional view taken along line AA in FIG. 4 is a cross-sectional view taken along line BB in FIG. 2, and FIG. 5 is a cross-sectional view taken along line CC in FIG.
[0025]
As shown in FIGS. 1 to 5, the ventilator 1 includes a box-shaped main body case 2 made of a metal panel. One side (left side in FIG. 1) of the main body case 2 has an indoor air inlet 3 and an outdoor air. An air supply port 4 is provided. One ends of ducts 5 and 6 are respectively attached to the indoor air suction port 3 and the outside air supply port 4, and the other ends of these ducts 5 and 6 are connected to respective rooms (not shown) in the building.
[0026]
In addition, an indoor air exhaust port 7 and an outside air intake port 8 are provided on the other side of the main body case 2 (right side in FIG. 1). One ends of ducts 9 and 10 are respectively attached to the indoor air exhaust port 7 and the outside air intake port 8, and the other ends of these ducts 9 and 10 are connected to an outer wall (not shown) of the building. A filter 11 that removes dust is attached to the outside air inlet 8.
[0027]
The interior of the main body case 2 is divided into one side space (the space on the left side in FIG. 1) and the other side space (the space on the right side in FIG. 1) by a partition wall 12 provided in the vertical direction. An inclined wall 13 is provided in the one side space. The inclined wall 13 is high on the vertical wall 14 side where the indoor air exhaust port 7 and the outside air intake port 8 are provided, and is low on the partition wall 12 side. A disc-shaped dehumidifying / humidifying rotor 15 is disposed at the center of the inclined wall 13.
[0028]
The one side space is divided into an upper space and a lower space by the inclined wall 13 and the dehumidifying / humidifying rotor 15, and the upper space is further divided vertically by the horizontal wall 16A and the lower space is divided by the horizontal wall 16B. Further, the upper space and the lower space are each divided into two chambers along the horizontal direction by the intermediate vertical wall 17. That is, in one side space in the main body case 2, chambers 18 and 19 are formed above the inclined wall 13, and chambers 20 and 21 are formed above the lateral wall 16 </ b> A, respectively. In one side space in the main body case 2, chambers 22 and 23 are formed below the inclined wall 13, and chambers 24 and 25 are formed below the lateral wall 16B, respectively. The duct 5 communicates with the chamber 25 and the duct 6 communicates with the chamber 22.
[0029]
On the other hand, the other side space of the main body case 2 is divided into upper and lower parts by a lateral wall 26, and a chamber 27 is formed below the lateral wall 26, and a chamber 28 is formed above the lateral wall 26. The duct 9 communicates with the chamber 27 and the duct 10 communicates with the chamber 28.
[0030]
In the partition wall 12, an opening 29 is formed between the chamber 19 and the chamber 27, and an opening 30 is formed between the chamber 20 and the chamber 28.
[0031]
The dehumidifying / humidifying rotor 15 is inclined at the same inclination angle as that of the horizontal wall 13, and the upper end surface center portion thereof is rotatably supported by the inclined portion 16a of the horizontal wall 16A and the lower end surface center portion thereof is rotatably supported by the inclined portion 16b of the horizontal wall 16B. ing. Further, the outer surface of the dehumidifying / humidifying rotor 15 is substantially uniformly exposed in the chambers 18 to 25.
[0032]
The dehumidifying / humidifying rotor 15 is made of cellulose or ceramic fiber impregnated with a hygroscopic agent such as silica gel, zeolite, or lithium chloride. Although not shown, the dehumidifying / humidifying rotor 15 is provided with a gear on the outer peripheral surface thereof, and, for example, a pinion or the like is engaged with the gear and the pinion is rotated, whereby the dehumidifying / humidifying rotor 15 is set in a predetermined direction. Can be rotated at a speed of In addition, the dehumidifying / humidifying rotor 15 can be similarly rotated at a predetermined speed in a certain direction by winding a belt around the outer periphery of the dehumidifying / humidifying rotor 15 and rotating the belt.
[0033]
Further, the dehumidifying / humidifying rotor 15 is formed with a large number of flutes (small holes) 15A, and through these flutes 15A, the chambers 18 and 24, the chambers 19 and 25, the chambers 20 and 22, and the chambers 21 and 23 are provided. Are in communication with each other. Each flute 15A is formed in a honeycomb structure.
[0034]
A heater 31 is installed as a room air heater below the dehumidifying / humidifying rotor 15 in the chamber 24, and a heater 32 is installed as an outside air heater above the dehumidifying / humidifying rotor 15 in the chamber 20. Although not shown, the heaters 31 and 32 are respectively fixed to the main body case 2.
[0035]
The chamber 27 is provided with an exhaust fan 33, and the chamber 28 is provided with an air supply fan 34. The exhaust fan 33 and the air supply fan 34 are connected to a rotation shaft 35 </ b> A of a motor 35 attached to the horizontal wall 26. A fan case 36 is provided near the exhaust fan 33, and a fan case 37 is provided near the air supply fan 34.
[0036]
Next, operation | movement of the ventilator 1 of the said structure is demonstrated. In FIG. 1, for easy understanding, the indoor air inlet 3, the outdoor air inlet 4, the indoor air outlet 7, the outdoor air inlet 8, the ducts 5, 6, 9, 10, and the openings 29, 30 are shown. , And heaters 31 and 32 are drawn on the same plane of the paper.
[0037]
First, when dehumidifying a room in summer or the like, the motor 35 is rotated to rotationally drive the exhaust fan 33 and the air supply fan 34, and only the heater 31 is energized. Then, the outside air OA outside the building is sucked into the room 28 through the duct 10 by the air supply fan 34 and further flows into the room 20 through the opening 30 of the partition wall 12 as shown in FIG. . Then, when the outside air OA flowing into the chamber 20 passes through the flute 15A of the dehumidifying / humidifying rotor 15, the moisture is absorbed by the hygroscopic agent impregnated in the dehumidifying / humidifying rotor 15, and then flows into the chamber 22 Further, the air is supplied as dry air supply SA to each room in the building via the duct 6.
[0038]
On the other hand, the indoor air RA is sucked into the exhaust fan 33 and flows into the chamber 25 through the duct 5. Then, the air is heated by the heater 31 and is sent to the dehumidifying / humidifying rotor 15 as warm air having a reduced relative humidity. When the warm air sent to the dehumidifying / humidifying rotor 15 passes through the flute 15A of the dehumidifying / humidifying rotor 15, the moisture absorbed by the hygroscopic agent is taken away from the dehumidifying / humidifying rotor 15, and thereafter, the chamber 19, the partition wall 12 Through the opening 29 and the chamber 27 and through the duct 9, the exhaust air is exhausted out of the building as warm exhaust air EA containing moisture.
[0039]
If the above operation is performed continuously, the indoor air RA is discharged to the outside of the building and, at the same time, fresh outdoor air OA is supplied to each room in the building, so that each room in the building can be ventilated. In addition, dehumidification of the supply air SA can be performed simultaneously with the ventilation.
[0040]
Next, when the room is humidified in winter or the like, the motor 35 is rotated to rotate the exhaust fan 33 and the air supply fan 34, and only the heater 32 is energized. Then, the indoor air RA is sucked into the exhaust fan 33 and flows into the chamber 25 through the duct 5. When the room air RA flowing into the chamber 25 passes through the dehumidifying / humidifying rotor 15, the moisture is absorbed by the hygroscopic agent impregnated in the dehumidifying / humidifying rotor 15, and then the chamber 19 and the partition wall 12. The air passes through the opening 29 and the chamber 27 and is exhausted out of the building through the duct 9 as dry exhaust air EA.
[0041]
On the other hand, outside air OA outside the building flows into the chamber 28 through the duct 10 by the air supply fan 34, and further flows into the chamber 20 through the opening 30 of the partition wall 12. The outside air OA that has flowed into the chamber 20 is heated by the heater 32 and is sent to the dehumidifying / humidifying rotor 15 as warm air having a reduced relative humidity. When the warm air sent to the dehumidifying / humidifying rotor 15 passes through the flute 15A of the dehumidifying / humidifying rotor 15, the moisture absorbed by the hygroscopic agent is taken away from the dehumidifying / humidifying rotor 15, and then passes through the chamber 22, The air is supplied to each room in the building through the duct 6 as a supply air SA containing moisture.
[0042]
If the above operation is performed continuously, the indoor air RA is discharged to the outside of the building and, at the same time, fresh outdoor air OA is supplied to each room in the building, so that each room in the building can be ventilated. In addition, the air supply SA can be humidified simultaneously with the ventilation.
[0043]
Next, when both the heaters 31 and 32 are not energized and only the exhaust fan 33 and the air supply fan 34 are rotationally driven, the room air RA sucked by the exhaust fan 33 and the air supply fan 34 are sucked in. When the outside air OA passes through the dehumidifying / humidifying rotor 15, total heat exchange (latent heat and sensible heat) can be performed between the room air RA and the outside air OA.
[0044]
That is, when only dehumidification is performed without dehumidification during cooling such as in summer, the heaters 31 and 32 are not energized, only the exhaust fan 33 and the supply fan 34 are rotated by the motor 35, and suction is performed by the exhaust fan 33. The cool indoor air RA and the warm outside air OA sucked by the air supply fan 34 exchange heat with each other when passing through the dehumidifying / humidifying rotor 27. As a result, the temperature of the exhaust air EA exhausted outside the building increases, and conversely, the temperature of the supply air SA supplied to each room in the building decreases, so that the reduction in cooling efficiency during ventilation is minimized. It becomes possible.
[0045]
Further, when only ventilation is performed without humidification during heating such as in winter, the heaters 31 and 32 are not energized, and only the exhaust fan 33 and the supply fan 34 are driven to rotate by the motor 35. Then, the warm room air RA sucked by the exhaust fan 33 and the cold outside air OA sucked by the air supply fan 34 exchange total heat with each other when passing through the dehumidifying / humidifying rotor 27. As a result, the temperature of the exhaust air EA discharged to the outside of the building is lowered, and conversely, the temperature of the supply air SA supplied to each room in the building is raised, so that a reduction in heating efficiency during ventilation is suppressed as much as possible. It becomes possible.
[0046]
The rotational speed of the dehumidifying / humidifying rotor 15 is set by the rotational speed switching means so as to be several tens of revolutions / minute during total heat exchange ventilation and several revolutions / minute during dehumidification or humidification. The rotational speed switching means changes the rotational speed of the dehumidifying / humidifying rotor 15 by switching the rotational speed of the motor stepwise or steplessly.
[0047]
In the present embodiment, since the dehumidifying / humidifying rotor 15 is installed in an inclined manner in the main body case 2, the outside air OA sucked by the air supply fan 34 in the chamber 20 is inclined to the flute 15 </ b> A of the dehumidifying / humidifying rotor 15. It will flow in from the direction, and the pressure loss of the outside air OA in the flute 15A can be kept small.
[0048]
Further, since the dehumidifying / humidifying rotor 15 is installed at an inclination, the length of the main body case 5 in the longitudinal direction can be reduced, and as a result, the entire ventilation device can be made compact.
[0049]
In the present embodiment, a ventilation device in which the heater 32 is omitted may be used. If the heater 32 is omitted, it does not have a humidifying function, so that the ventilator has only a dehumidifying function.
[0050]
In the present embodiment, the entire ventilation device 1 is a concealment type ventilation device that is hidden behind the ceiling. However, the ventilation device 1 is a so-called semi-concealment type ventilation device having a bottom exposed from the ceiling. There may be. In this case, as shown in FIG. 1B, an indoor air suction opening 2 </ b> B is formed on the bottom wall of the main body case 2 (the bottom wall of the chamber 25) instead of the indoor air suction port 3. Then, the indoor air RA is caused to flow into the chamber 25 of the main body case 2 through the indoor air suction opening 2B.
[0051]
Furthermore, as shown in FIG.1 (c), in addition to the indoor air suction inlet 3 and the duct 5, you may form the indoor air suction opening 2B in the bottom wall of the main body case 2 (bottom wall of the chamber 25). In this case, the room air RA flows into the chamber 25 of the main body case 2 through both the duct 5 and the room air suction opening 2B.
[0052]
(Embodiment 2)
6 to 11 show a ventilator according to Embodiment 2, FIG. 6 is a longitudinal sectional view thereof, FIG. 7 is a transverse sectional view, FIG. 8 is a transverse sectional view showing a heater position, and FIG. FIG. 10 is a cross-sectional view taken along line E-E in FIG. 7, and FIG. 11 is a cross-sectional view taken along line F-F in FIG. 7.
[0053]
The ventilator 1 of the present embodiment includes a box-shaped main body case 2 as in the first embodiment. However, in the present embodiment, the position of the duct attached to the main body case 2 is different from that in the first embodiment. That is, an indoor air exhaust port 7 and an outside air intake port 8 are provided on one side of the main body case 2 (left side in FIG. 6). Ducts 9 and 10 are respectively attached to the indoor air exhaust port 7 and the outside air intake port 8. In addition, an indoor air suction port 3 and an outside air supply port 4 are provided on the other side of the main body case 2 (right side in FIG. 6). Ducts 5 and 6 are respectively attached to the indoor air inlet 3 and the outside air inlet 4.
[0054]
In the present embodiment, the one side space (the left space in FIG. 6) in the main body case 2 divided by the partition wall 12 is divided into an upper space and a lower space by the horizontal wall 41, and further, the upper space and the lower space The space is divided into two chambers along the horizontal direction by the intermediate vertical wall 42. That is, chambers 43 and 44 are formed below the lateral wall 41, and chambers 45 and 46 are formed above the lateral wall 41.
[0055]
The dehumidifying / humidifying rotor 15 is horizontally installed at the center of the lateral wall 41. The dehumidifying / humidifying rotor 15 is rotatably attached to an end portion of a support shaft 47 fixed to the upper wall 2A of the main body case 2. The outer surface of the dehumidifying / humidifying rotor 15 is substantially uniformly exposed in the chambers 43 and 44 below the lateral wall 41 and in the chambers 45 and 46 above the lateral wall 41. The horizontal wall 41 may be provided obliquely and the dehumidifying / humidifying rotor 15 may be installed inclined.
[0056]
The other side space (the right side space in FIG. 6) in the main body case 2 is divided into upper and lower parts by a horizontal wall 26 as in the first embodiment, and a chamber 27 and a chamber 28 are formed. Then, an air supply fan 34 is provided in the chamber 27, and an exhaust fan 33 is provided in the chamber 28. The air supply fan 34 and the exhaust fan 33 are rotationally driven by a motor 35.
[0057]
In the present embodiment, the air rectifying member 48 is provided in a substantially half space on the side close to the vertical wall 12 in the chamber 45. The air rectifying member 48 is provided with a plurality of fins 48A in a direction perpendicular to the flow of the room air RA discharged from the exhaust fan 33, and a gap is formed between the fins 48A for the air flow. ing. Each fin 48 </ b> A increases in height with distance from the exhaust fan 33, and the top end thereof is equally inclined toward the exhaust fan 33. Each fin 48A is supported at both ends by a support plate 48B and has a strength to withstand the flow of the outside air OA discharged from the exhaust fan 33. The air rectifying member 48 is fixed to the main body case 2.
[0058]
Further, a heater 49 for room air is provided below the air rectifying member 48 (see FIG. 8). The heater 49 is disposed obliquely with respect to the fins 48 </ b> A of the air rectifying member 48.
[0059]
Next, operation | movement of the ventilation apparatus 1 by this Embodiment is demonstrated. In FIG. 6, for easy understanding, the indoor air suction port 3, the outdoor air supply port 4, the indoor air discharge port 7, the outdoor air suction port 8, the ducts 5, 6, 9, 10 and the openings 29 and 30. , And the heater 49 are drawn on the same surface of the paper.
[0060]
First, when dehumidifying the room, the exhaust fan 33 and the air supply fan 34 are driven to rotate, and the heater 49 is energized. Then, outside air OA outside the building is sucked by the air supply fan 34 and flows into the room 46 through the duct 10. When the outside air OA flowing into the chamber 46 passes through the flute 15 </ b> A of the dehumidifying / humidifying rotor 15, the moisture is absorbed by the moisture absorbent impregnated in the dehumidifying / humidifying rotor 15. Thereafter, the outside air OA flows into the chamber 44, and is further supplied as dry air supply SA to each room in the building through the opening 29 of the partition wall 12, the chamber 27, and the duct 6.
[0061]
On the other hand, the indoor air RA is sucked into the exhaust fan 33 and flows into the chamber 28 through the duct 5, and further flows into the chamber 45 through the opening 30 of the partition wall 12. The room air RA that has flowed into the chamber 45 flows into the gap between the fins 48 </ b> A from the opening portions of the fins 48 </ b> A of the air rectifying member 48, further heated by the heater 49, and then sent to the dehumidifying / humidifying rotor 15. At this time, the flow direction of the indoor air RA is substantially downward by the air rectifying member 48 (substantially perpendicular to the upper end surface of the dehumidifying / humidifying rotor 15), and smoothly flows into the flute 48A of the dehumidifying / humidifying rotor 48. As a result, the pressure loss of the indoor air RA in the flute 48A can be kept small.
[0062]
The room air RA heated by the heater 49 and having decreased in relative humidity takes away moisture absorbed by the hygroscopic agent from the dehumidifying / humidifying rotor 15 when passing through the flute 15A of the dehumidifying / humidifying rotor 15, and then the chamber 43 The air is exhausted out of the building through the duct 9 as warm exhaust air EA containing moisture.
[0063]
If the above operation is performed continuously, the indoor air RA is discharged to the outside of the building and, at the same time, fresh outdoor air OA is supplied to each room in the building, so that each room in the building can be ventilated. In addition, dehumidification of the supply air SA can be performed simultaneously with the ventilation.
[0064]
If a heater for the outside air is installed in the chamber 46 near the upper end surface of the dehumidifying / humidifying rotor 15, each room in the building can be humidified by energizing only the heater for the outside air and operating the ventilator. Is possible. Further, ventilation of each room in the building can be performed only by rotating the exhaust fan 33 and the air supply fan 34 without energizing the heater 49.
[0065]
Most of the room air RA exhausted from the exhaust fan 33 flows along the inner surface of the main body case 2. According to the present embodiment, since the air rectifying member 48 is disposed on the side close to the exhaust fan 33 and a gap is formed between the upper portion of the air rectifying member 48 and the inner surface of the main body case 2, Of the exhausted room air RA, room air having a high wind speed flowing along the inner surface of the main body case 2 is sent to the dehumidifying / humidifying rotor 15 without being heated, and the room air having a low wind speed is led to the heater 49 by the air rectifying member 48. Can be heated.
[0066]
The amount of heat of the heater 49 is set to a constant value. When indoor air with a high wind speed is applied to the heater 49, the temperature of the indoor air does not rise sufficiently, so the relative humidity does not decrease and the dehumidifying / humidifying rotor 15 does not release moisture. In the present embodiment, the indoor air having a low wind speed is guided to the heater 49 by the air rectifying member 48 in the present embodiment, so that the temperature of the indoor air is sufficiently increased and the relative humidity is decreased. The moisture release will be sufficient.
[0067]
(Embodiment 3)
12 to 15 show a ventilating apparatus according to Embodiment 3, FIG. 12 is a longitudinal sectional view thereof, FIG. 13 is a transverse sectional view, and FIG. 14 is a sectional view taken along line GG in FIG. 15 is a cross-sectional view taken along line HH in FIG. In addition, the arrow view along the DD line | wire of FIG. 13 is the same as FIG.
[0068]
In the present embodiment, in the chamber 45, a heater 51 for room air is installed in the vicinity of the upper end surface of the dehumidifying / humidifying rotor 15. The heater 51 is disposed in the chamber 45 away from the exhaust fan 33, that is, on the side close to the vertical wall 14 provided with the indoor air exhaust port 7 and the outside air intake port 8. Further, the heater 51 is installed along the radial direction of the dehumidifying / humidifying rotor 15 and is disposed obliquely with respect to the flow of the room air RA discharged from the exhaust fan 33. Except for the point that the air rectifying member 48 is not installed, the other configuration is the same as that of the second embodiment.
[0069]
Most of the room air RA discharged from the exhaust fan 33 flows along the upper inner surface of the main body case 2. According to the present embodiment, of the room air RA discharged from the exhaust fan 33, only the room air having a high wind speed flowing along the upper inner surface of the main body case 2 can be intensively heated by the heater 51.
[0070]
The flow of room air RA, exhaust air EA, outside air OA, and air supply SA during ventilation and dehumidification is the same as in the second embodiment.
[0071]
Further, in the chamber 46, if an outdoor air heater 54 (see FIG. 13) is installed in the vicinity of the upper end surface of the dehumidifying / humidifying rotor 15, by energizing only the heater 54 and operating the ventilator, It is also possible to humidify the room. Furthermore, it is possible to ventilate each room in the building simply by rotating the exhaust fan 33 and the air supply fan 34 without energizing the heater 51.
[0072]
Further, in the present embodiment, as shown in FIGS. 16 and 17, the one exhausted from the exhaust fan 33 on the downstream side of the heater 16 along the rotation direction (arrow A direction) of the dehumidifying / humidifying rotor 15. A blocking member 52 is provided at a location where the room air hits, that is, on the side close to the partition wall 12 in the chamber 45. The blocking member 52 has a fan shape whose radius is slightly larger than that of the dehumidifying / humidifying rotor 51, and is installed above the dehumidifying / humidifying rotor 15 and below the opening 30 of the partition wall 12.
[0073]
In addition, a partition plate 53 is provided below the dehumidifying / humidifying rotor 15, and the partition plate 53 allows the chamber 43 to be divided into a chamber 43 </ b> A near the vertical wall 14 and a chamber 43 </ b> B near the partition wall 12. It is divided.
[0074]
In the room air RA exhausted from the exhaust fan 33, apart from much room air flowing along the inner surface of the main body case 2, a part of the room air RA that is exhausted from the exhaust fan 33 and immediately flows into the dehumidifying / humidifying rotor 15. There is no room air. Such a part of room air is not heated by the heater 51, that is, flows into the dehumidifying / humidifying rotor 15 without lowering the relative humidity, so that the moisture is absorbed by the dehumidifying / humidifying rotor.
[0075]
However, when the dehumidifying / humidifying rotor 15 absorbs moisture, the hygroscopic ability decreases, and the original function of absorbing moisture from the outside air OA sucked by the air supply fan 34 is adversely affected.
[0076]
Therefore, if the blocking member 52 is provided as described above, it is possible to prevent some room air from flowing directly into the dehumidifying / humidifying rotor 15 without being heated by the heater 15. Moisture is not absorbed from the indoor air RA, and a decrease in the moisture absorption capability of the dehumidifying / humidifying rotor 15 can be suppressed.
[0077]
Further, in the above configuration, the room air RA that has passed through the heater 51 takes moisture from the dehumidifying / humidifying rotor 15 and is exhausted from the duct 9 as exhaust air EA containing a large amount of moisture. When a part of the exhaust air EA after passing contacts the dehumidifying / humidifying rotor 15 below the blocking member 52, the dehumidifying / humidifying rotor 15 absorbs moisture in the exhausted air EA, and the hygroscopic capacity decreases as described above. To do.
[0078]
In the present embodiment, the partition plate 53 is provided below the dehumidifying / humidifying rotor 15, and the chamber 43 is divided into the chamber 43 </ b> A and the chamber 43 </ b> B. It does not flow into 43B and is exhausted through only the chamber 43A. Thereby, the fall of the moisture absorption capability of the dehumidification / humidification rotor 15 can be suppressed further.
[0079]
In the first to third embodiments, an opening may be provided on the lower surface of the main body case 2 and the indoor air RA may be sucked from the opening instead of the indoor air suction port 3 and the duct 5. Further, the opening may be further added to the indoor air suction port 3 and the duct 5, and the indoor air RA may be sucked from both the indoor air suction port 3, the duct 5, and the opening. If it does in this way, it will be applicable to either a ceiling embedded type or a ceiling cassette type ventilation device.
[0080]
(Embodiment 4)
18 and 19 show a ventilator according to Embodiment 4, FIG. 18 is a longitudinal sectional view thereof, and FIG. 19 is a transverse sectional view thereof.
[0081]
In the present embodiment, the indoor air exhaust port 7 and the outside air inlet 8 are on one side (left side in FIG. 18) of the main body case 2, and the indoor air inlet 3 and the outside air inlet are on the other side (right side in FIG. 18). 4 are provided. A duct 9 is attached to the indoor air exhaust port 7, a duct 10 is attached to the outdoor air inlet 8, a duct 5 is attached to the indoor air inlet 3, and a duct 6 is attached to the outdoor air inlet 4.
[0082]
Further, an inclined wall 61 is provided in one side space (the space on the left side in FIG. 18) divided by the partition wall 12 in the main body case 2, and this inclined wall 61 is hung between the vertical wall 14 and the partition wall 12. Has been passed. One end of the inclined wall 61 is fixed to the vertical wall 14 at the lower side of the indoor air exhaust port 7, and the other side is fixed to the partition wall 12 at the upper side of the opening 29. The vertical wall 14 side is high and the partition wall 12 side is low. ing. A disc-shaped dehumidifying / humidifying rotor 15 is rotatably provided at the center of the inclined wall 61. The dehumidifying / humidifying rotor 15 is rotationally driven in a plane parallel to the inclined wall 61 by a rotation drive mechanism (not shown). The
[0083]
The one side space is divided into an upper space and a lower space by the inclined wall 61 and the dehumidifying / humidifying rotor 15, and the upper space and the lower space are respectively divided into two along the horizontal direction by an intermediate vertical wall 62 provided in the vertical direction. It is divided into rooms. Thereby, chambers 63 and 64 are formed above the inclined wall 61 and chambers 65 and 66 are formed below the inclined wall 61 in one side space in the main body case 2, respectively. The dehumidifying / humidifying rotor 15 has its outer surface exposed substantially uniformly in the chambers 63 to 66. The duct 9 communicates with the chamber 64 and the duct 10 communicates with the chamber 65.
[0084]
In the present embodiment, the chamber 65 has an outdoor air heater 32 near the lower side of the dehumidifying / humidifying rotor 15, and the chamber 66 has an indoor air heater 31 near the lower side of the dehumidifying / humidifying rotor 15. Each is provided.
[0085]
On the other hand, chambers 27 and 28 are formed in the other side space (the space on the right side in FIG. 18) divided by the partition wall 12 in the main body case 2, the exhaust fan 33 is provided in the chamber 27, and the chamber 28 is supplied with air. Each fan 34 is provided. The duct 5 communicates with the chamber 27, and the duct 6 communicates with the chamber 28. Reference numeral 36A denotes a fan case for the exhaust fan 33, and reference numeral 37A denotes a fan case for the air supply fan 34. Other configurations are the same as those in the first embodiment.
[0086]
Next, operation | movement of the ventilator 1 of the said structure is demonstrated.
First, when dehumidifying the room, the exhaust fan 33 and the air supply fan 34 are driven to rotate, and only the heater 31 is energized. Then, outside air OA outside the building flows into the chamber 65 through the duct 10 and is further sent to the dehumidifying / humidifying rotor 15. When the outside air OA sent to the dehumidifying / humidifying rotor 15 passes through the flute 15A of the dehumidifying / humidifying rotor 15, the moisture is absorbed by the hygroscopic agent impregnated in the dehumidifying / humidifying rotor 15, and then into the chamber 63. Inflow. Further, the outside air OA flowing into the chamber 63 passes through the opening 30 of the partition wall 12 and is supplied as dry air supply SA to the rooms in the building via the chamber 28 and the duct 6.
[0087]
On the other hand, the room air RA is sucked by the exhaust fan 33 and flows into the chamber 27 through the duct 5 and flows into the chamber 66 through the opening 29 of the partition wall 12. Then, the air is heated by the heater 31 and is sent to the dehumidifying / humidifying rotor 15 as warm air having a reduced relative humidity. When the hot air sent to the dehumidifying / humidifying rotor 15 passes through the flute 15A of the dehumidifying / humidifying rotor 15, the moisture absorbed by the hygroscopic agent is taken away from the dehumidifying / humidifying rotor 15, and then the chamber 64 and the duct 9 are removed. The air is exhausted out of the building as warm exhaust air EA containing moisture.
[0088]
If the above operation is performed continuously, the indoor air RA is discharged to the outside of the building and, at the same time, fresh outdoor air OA is supplied to each room in the building, so that each room in the building can be ventilated. In addition, dehumidification of the supply air SA can be performed simultaneously with the ventilation.
[0089]
Next, when the room is humidified, the exhaust fan 33 and the air supply fan 34 are rotationally driven, and only the heater 32 is energized. Then, the indoor air RA is sucked into the exhaust fan 33 and flows into the chamber 27 through the duct 5. The room air RA flowing into the chamber 27 flows into the chamber 66 through the opening 29 of the partition wall 12 and is sent to the dehumidifying / humidifying rotor 15. When the room air RA passes through the dehumidifying / humidifying rotor 15, the moisture is absorbed by the moisture absorbent impregnated in the dehumidifying / humidifying rotor 15, and then the exhausted air EA dried through the chamber 64 and the duct 9. Are discharged outside the building.
[0090]
On the other hand, outside air OA outside the building flows into the room 65 through the duct 10 by the air supply fan 34. The outside air OA that has flowed into the chamber 65 is heated by the heater 32 and is sent to the dehumidifying / humidifying rotor 15 as warm air having a reduced relative humidity. When the hot air sent to the dehumidifying / humidifying rotor 15 passes through the flute 15 </ b> A of the dehumidifying / humidifying rotor 15, the moisture absorbed by the hygroscopic agent is taken away from the dehumidifying / humidifying rotor 15 and flows into the chamber 63. Thereafter, the outside air OA flows to the room 28 through the opening 30 of the partition wall 12, and is further supplied to each room in the building as a supply air SA containing moisture through the duct 6.
[0091]
If the above operation is performed continuously, the indoor air RA is discharged to the outside of the building and, at the same time, fresh outdoor air OA is supplied to each room in the building, so that each room in the building can be ventilated. In addition, the air supply SA can be humidified simultaneously with the ventilation.
[0092]
When both the heaters 31 and 32 are not energized and only the exhaust fan 33 and the air supply fan 34 are rotationally driven, the room air RA sucked by the exhaust fan 33 and the air supply fan 34 are sucked. When the outside air OA passes through the dehumidifying / humidifying rotor 15, total heat exchange (latent heat and sensible heat) can be performed between the room air RA and the outside air OA.
[0093]
In the present embodiment, the entire ventilation device 1 is a concealment type ventilation device that is hidden behind the ceiling. However, the ventilation device 1 is a so-called semi-concealment type ventilation device having a bottom exposed from the ceiling. There may be. In this case, as shown in FIG. 18B, instead of the indoor air suction port 3, an indoor air suction opening 2C is formed in the bottom wall of the main body case 2 (the bottom wall of the chamber 27). The room air RA is caused to flow into the chamber 27 of the main body case 2 through the room air suction opening 2C.
[0094]
Furthermore, as shown in FIG. 18C, in addition to the indoor air suction port 3 and the duct 5, an indoor air suction opening 2C may be formed in the bottom wall of the main body case 2 (the bottom wall of the chamber 27). In this case, the room air RA flows into the chamber 27 of the main body case 2 through both the duct 5 and the room air suction opening 2C.
[0095]
(Embodiment 5)
FIG. 20 shows the fifth embodiment. This Embodiment is an example which installed the ventilation apparatus 1 shown in the said Embodiment 1-4 in the detached house (dwelling unit). The ventilation device 1 is installed on the ceiling of the passage 71 in the house 70. A branch chamber 72 is attached to the duct 6 (duct through which the supply air SA passes) attached to the ventilator 1, and the duct 6 is branched into three ducts 6A, 6B, and 6C by the branch chamber 72. An air supply port 73 is attached to each end of the branched ducts 6A, 6B, 6C. Of these air supply ports 73, two air supply ports are connected to the dining / living room 74 and the remaining one air supply port. Are provided in the Japanese-style room 75, respectively.
[0096]
An indoor air suction opening 77 opened to the washroom 76 is attached to the tip of the duct 5 (duct through which room air RA passes) attached to the ventilation device 1. An exhaust hood 78 is provided at the tip of the duct 9 (the duct through which the exhaust air EA passes), and a suction hood 79 is provided at the tip of the duct 10 (the duct through which the outside air OA passes). It is fixed to the outer wall.
[0097]
In the above configuration, the indoor air RA is sucked into the ventilator 1 and then discharged into the outside air as exhaust air EA, and the outside air OA is sucked into the ventilator 1 and then supplied to the dining / living room 74 and the Japanese-style room 75. It is supplied as SA and ventilated, and during this ventilation, total heat exchange, dehumidification or humidification is performed between the room air RA and the outside air OA.
[0098]
The supply air SA supplied to the dining / living room 74 becomes room air RA and flows through the undercut portion (not shown) below the sliding door 80 as shown by the arrow A, and the supply air SA supplied to the Japanese-style room 75 is also the same. Then, it becomes room air RA, flows through an undercut portion (not shown) below the door 81 as shown by arrow B, is collected in the washroom 76, and flows into the ventilator 1 through the room air suction opening 77.
[0099]
If the indoor air suction opening 2B (see FIG. 1B) or the indoor air suction opening 2C (see FIG. 18B) is formed in the main body case 2, the interior of the dining / living room 74 or the Japanese-style room 75 Indoor air RA is collected in the passage 71 and flows into the ventilator 1 through the indoor air suction opening 2B or 2C.
[0100]
In addition, in addition to the duct 5, the indoor air suction opening 2 </ b> B (see FIG. 1B) and the indoor air suction opening 2 </ b> C (see FIG. 18B) are formed in the main body case 2. The room air RA in the room 74 and the Japanese-style room 75 is collected in the passage 71 and flows into the ventilator 1 through the room air suction opening 2B or 2C, and the room air RA in the washroom 76 is the room air suction opening 77. It flows into the ventilator 1 via.
[0101]
【The invention's effect】
As described above, according to the present invention, air is introduced into the flute of the dehumidifying / humidifying rotor by installing the dehumidifying / humidifying rotor in an inclined manner in the case of the ventilator body or by providing an air rectifying member. The pressure loss at the flute inlet can be kept small.
[0102]
In addition, by installing the dehumidifying / humidifying rotor at an inclination, the length of the ventilation device main body in the longitudinal direction can be reduced, and the entire ventilation device can be made compact.
[0103]
Furthermore, by installing a room air heater at a location where much of the room air exhausted from the exhaust fan and flowing along the inner surface of the case hits, only room air with a high wind speed is heated intensively by the room air heater. Therefore, the indoor air can be efficiently heated. As a result, it can contribute to energy saving.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of a ventilation device according to a first embodiment.
FIG. 2 is a cross-sectional view of the ventilation device shown in FIG.
FIG. 3 is an arrow view taken along the line AA in FIG. 2;
4 is a cross-sectional view taken along line BB in FIG.
5 is a cross-sectional view taken along the line CC in FIG. 2. FIG.
6 is a longitudinal sectional view of a ventilation device according to Embodiment 2. FIG.
7 is a cross-sectional view of the ventilation device shown in FIG. 6. FIG.
FIG. 8 is a cross-sectional view of the ventilation device showing a heater position.
FIG. 9 is a view taken along the line DD in FIG. 7;
10 is a cross-sectional view taken along the line EE of FIG.
11 is a cross-sectional view taken along line FF in FIG.
FIG. 12 is a longitudinal sectional view of a ventilation device according to a third embodiment.
13 is a cross-sectional view of the ventilation device shown in FIG.
14 is a cross-sectional view taken along the line GG in FIG.
15 is a cross-sectional view taken along line HH in FIG.
FIG. 16 is a longitudinal sectional view of a ventilation device provided with a blocking member.
FIG. 17 is a cross-sectional view of a ventilation device provided with a blocking member.
FIG. 18 is a longitudinal sectional view of a ventilation device according to a fourth embodiment.
FIG. 19 is a cross-sectional view of the ventilation device shown in FIG.
FIG. 20 is a plan view of a detached house according to a fifth embodiment.
[Explanation of symbols]
1 Ventilator
2 Body case
3 Indoor air inlet
4 Outside air supply port
7 Indoor air exhaust
8 Outside air inlet
13,61 inclined wall
15 Dehumidifying / humidifying rotor
15A flute
18-25, 27, 28, 63-66 rooms
31, 49, 51 Heater for indoor air
32 Heater for outside air
33 Exhaust fan
34 Air supply fan
35 motor
48 Air rectifier
48A Fin
48B support plate
52 Blocking member
53 Partition plate
70 housing

Claims (7)

A ventilation device that sucks indoor air and exhausts it outside the building, sucks outside air outside the building and supplies it into the room, and ventilates the room in the building,
A rotor for transferring moisture between the room air and the outside air while rotating and for performing total heat exchange and at least dehumidifying or humidifying is installed in a tilted manner in the case of the ventilator body. Ventilation equipment to do. An exhaust fan that sucks indoor air and exhausts it outside the building;
An air supply fan that sucks in outside air outside the building and supplies it into the room;
It is provided over both the air path through which the room air flows and the air path through which the outside air flows, and exchanges moisture between the room air and the outside air while rotating, and performs total heat exchange and at least dehumidification or humidification. Rotor to do,
A ventilator provided with an indoor air heater arranged on the upstream side of the rotor along the flow of the indoor air and capable of heating the indoor air flowing into the rotor,
A ventilator characterized in that the rotor is installed in an inclined manner in a case of a ventilator body. An exhaust fan that sucks indoor air and exhausts it outside the building;
An air supply fan that sucks air outside the building and supplies it into the room;
An apparatus body case in which the exhaust fan and the air supply fan are stored;
It is arranged over both the air path of the air sucked by the exhaust fan and the air path of the air sucked by the air supply fan, and is installed in a state of being horizontal or inclined in the case of the ventilator main body, A rotor that transfers moisture between the two airs while rotating;
A ventilator provided with a heater arranged on the upstream side of the rotor along the flow of each air and capable of heating each air flowing into the rotor,
A ventilator comprising an air rectifying member which is arranged on the upstream side of the heater along the flow of each air and rectifies the air sent by each fan toward the rotor. An exhaust fan that sucks indoor air and exhausts it outside the building;
An air supply fan that sucks air outside the building and supplies it into the room;
An apparatus body case in which the exhaust fan and the air supply fan are stored;
It is arranged over both the air path of the air sucked by the exhaust fan and the air path of the air sucked by the air supply fan, and is installed in a state of being horizontal or inclined in the case of the ventilator main body, A rotor that transfers moisture between the two airs while rotating;
A ventilator provided with a heater arranged on the upstream side of the rotor along the flow of each air and capable of heating each air flowing into the rotor,
The ventilator characterized by arrange | positioning the said heater in the place where most of each said air which was sent by the said each fan and flowed along the said case inner surface hits. When heating the air sucked by the exhaust fan, the heater is installed at a location away from the exhaust fan and obliquely to the air flow, and heats the air sucked by the air supply fan. When it does, the ventilation apparatus of Claim 4 installed in the place near the said air supply fan, and diagonally with respect to the said air flow. A blocking member that prevents the partial air from flowing into the rotor at a location where the partial air sent by the fans hits the downstream side of the heater along the rotation direction of the rotor. The ventilator according to claim 4 or 5, wherein is provided. A housing structure comprising the ventilator according to claim 1.

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