JP2001099453A - Humidifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidifier having a high humidifying efficiency by reducing air between a humidifying channel and a moisture-absorption channel. SOLUTION: A moisture-absorption-side fan motor 14 and a humidifying-side fan motor 17 are provided downstream of a humidifying rotor 12 to produce a negative pressure in both of a humidifying channel 13 and a moisture- absorption channel 15 in the vicinity of the end surfaces of the humidifying rotor 12. As a result, the difference in pressure between air in the humidifying channel 15 and air in the moisture-absorption channel 13 is small in the vicinity of the end surfaces of the humidifying rotor 12 and consequently leakage of air is reduced so that the humidifying efficiency is improved. Both of the moisture-absorption-side fan motor 14 and the humidifying-side fan motor 17 are arranged at the same lower side of the humidifying rotor 12 to miniaturize the humidifier.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a humidifying device for humidifying, for example, air supplied to a room. More specifically, the present invention relates to a humidifying device for collecting and supplying moisture from air without providing a water supply device. The present invention relates to a humidifying device that performs humidification.

[0002]

2. Description of the Related Art Conventionally, as a humidifier of this type, FIG.
(JP-A-8-141345). In this humidifying device, a humidifying rotor 2 made of an adsorbent such as silica gel or zeolite is disposed in a casing 1. The humidification rotor 3 passes through the humidification passage 3 and the humidification passage 5, and the humidification rotor 2 performs a moisture adsorption operation in the humidification passage 3 and performs a desorption operation of the moisture in the humidification passage 5. A fan 6 is provided upstream of the humidification rotor 2 in the moisture absorption passage 3,
Air is flowed as shown by arrows A and B, and the humidification rotor 2 absorbs moisture from the air in the moisture absorption passage 3. On the other hand, a fan 7 and a heater 8 are provided upstream of the humidification rotor 2 in the humidification passage 5 so that air flows through the humidification passage 5 as shown by arrows C and D. The humidification passage 5 which is pressure-fed by the fan 7 and heated by the heater 8
Is humidified by the humidification rotor 2 (humidification rotor 2
) And is supplied to the indoor unit through a pipe (not shown).

In this humidification device, the humidification rotor 2 absorbs moisture from the air in the humidification passage 3 and discharges the moisture from the humidification rotor 2 to the air in the humidification passage 5, so that a water supply device is unnecessary. It has the advantage of being.

[0004]

However, in the above-mentioned conventional humidifier, since the fan 6 on the side of the humidifying passage 3 and the fan 7 on the side of the humidifying passage 5 are located on the upstream side with respect to the humidifying rotor 2, the following. There's a problem. In general, a large amount of air (for example, 3 m ³ / min) flows through the moisture absorbing passage 3 to collect moisture from the air. However, the sectional area of the moisture absorbing passage 3 is relatively large, and the humidifying rotor 2 is The pressure at point M upstream of the humidification rotor 2 in the moisture absorption passage 3 is about 7 mm water column, since the fan 6 only gives enough pressure to pass through. On the other hand, a relatively small amount of air (for example, 0.2 m ³ / min) is supplied to the humidifying passage 5, but the humidifying passage 5 has a relatively small cross-sectional area, and
On the side, the pressure at point L downstream of the humidification fan 2 in the humidification passage 5 is 50 to 80 mm water column to overcome the resistance of the long pipe to the indoor unit. Therefore, the point M
The pressure difference between the humidification passage 5 and the point L becomes approximately 43 to 73 mm water column, and there is a problem that a large amount of humidified air in the humidification passage 5 leaks to the moisture absorption passage 3 side. Since the humidification rotor 2 rotates about the axis 2a, the wall 9 between the points L and M and the humidification rotor 2
There is a gap between them. A large amount of humidified air leaks from this gap due to the large pressure difference. Due to the leakage of the humidified air, the humidification efficiency (humidification amount / input) deteriorates.

It is an object of the present invention to provide a humidifier having a high humidifying efficiency with less air leakage between the humidifying passage and the humidifying passage.

[0006]

In order to achieve the above object, a humidifying apparatus according to the first aspect of the present invention comprises a humidifying rotor, a humidifying passage passing through the humidifying rotor, and a humidifying fan provided in the humidifying passage. A humidifying fan passing through the humidifying rotor, and a humidifying fan provided in the humidifying passage (referred to as a humidifying fan in the sense of a fan on the humidifying passage side). And a heating means for heating the air in the humidifying passage, wherein the humidifying rotor absorbs moisture from the air in the humidifying passage while humidifying the heated air in the humidifying passage. The humidification fan is provided in a humidification passage downstream of the humidification rotor, and the humidification fan is provided in a humidification passage downstream of the humidification rotor.

In the humidifying device having the above structure, both the humidifying fan and the humidifying fan are provided on the downstream side of the humidifying rotor. In the vicinity of the end surface of the humidifying rotor, both the humidifying passage and the humidifying passage have a negative pressure. It does not have a high positive pressure like the humidified air being pumped at the outlet side. Therefore, the pressure difference between the air in the humidifying passage and the air in the humidifying passage near the end face of the humidifying rotor, or between the air in the humidifying passage and the outside air is small, and air leakage in the humidifying passage or leakage to the humidifying passage is prevented. There is little invasion of outside air. Therefore, the humidification efficiency is improved.

A humidifying device according to a second aspect of the present invention is the humidifying device according to the first aspect, wherein the humidifying passage is directly adjacent to the humidifying passage near the humidifying rotor.

[0009] In the humidifier having the above structure, the first aspect of the present invention is described.
Since the pressure difference between the air in the humidifying passage and the air in the humidifying passage is small near the end surface of the humidifying rotor as in the humidifying device of the invention, the humidifying passage is connected to the humidifying passage near the humidifying rotor. Even if it is directly adjacent, there is little air leakage in the humidifying passage.

According to a third aspect of the present invention, in the humidifying apparatus according to the first aspect, the humidifying passage is adjacent to the humidifying passage via an outside air portion near the humidifying rotor. Features.

In the humidifying device having the above structure, since the humidifying passage is adjacent to the humidifying passage through the outside air portion in the vicinity of the humidifying rotor, the pressure difference between the humidifying passage and the outside air portion is humidified. The pressure difference between the passage and the moisture absorption passage can be made smaller. Therefore, leakage between the outside air part and the humidifying passage can be reduced. Further, since the humidifying side and the moisture absorbing side are not influenced by the pressure fluctuation of the other party, a constant flow can be maintained in each passage, and the performance is stabilized.

A humidifying device according to a fourth aspect of the present invention is the humidifying device according to any one of the first to third aspects, wherein the humidifying rotor has a humidifying passage in which moisture is desorbed by air in the humidifying passage heated by the heating means. It is characterized in that the air to be humidified is preheated to the portion, and the preheated air is heated by the heating means and passed through the humidification rotor.

In the humidifying device having the above-mentioned structure, after the air to be humidified is preheated to the humidifying rotor portion where the moisture is desorbed by the air heated by the heating means, the preheated air is heated by the heating means. . Therefore, the load on the heating means can be reduced, the heating means can be downsized, and energy saving can be achieved. In particular, the humidification efficiency is greatly improved due to the fact that the air leakage from the humidification passage or the air leakage to the humidification passage is small, and this preheating is combined.

A humidifying device according to a fifth aspect of the present invention is the humidifying device according to any one of the first to fourth aspects, wherein the humidifying fan and the humidifying fan are arranged on one side of the humidifying rotor. It is characterized by.

In the humidifying device having the above configuration, the humidifying fan and the humidifying fan are arranged on one side of the humidifying rotor. The overall dimensions of the humidifier in the axial direction are reduced. Therefore, a small and compact humidifying device is provided in addition to a small air leakage and a high humidifying efficiency.

According to a sixth aspect of the present invention, in the humidifying apparatus according to any one of the first to fifth aspects, a heater as the heating means is provided in a humidifying passage above the humidifying rotor. The humidification fan is provided below the humidification rotor.

In the humidifying device having the above structure, the heater is arranged above the humidifying rotor, so that even if dew condensation occurs on the humidifying rotor or the like, the heater does not leak. The air heated by the heater is sucked below the humidifying rotor by a humidifying fan.

A humidifying device according to a seventh aspect of the present invention is the humidifying device according to any one of the first to sixth aspects, wherein a hole is provided in a bottom portion of a case of a motor for driving the humidifying fan. I have.

In the humidifying device having the above-mentioned structure, water droplets condensed in the case of the motor of the humidifying fan are discharged from the hole of the case. Therefore, the motor does not fail. Further, generation of abnormal noise and deterioration of parts due to water are prevented.

According to an eighth aspect of the present invention, in the humidifying apparatus according to the seventh aspect, a protective cover is provided near the hole of the case.

In the humidifying device having the above structure, the protective cover is provided near the hole of the case of the motor of the humidifying fan. Therefore, even if steam is blown out from the hole, the protective cover is blocked by other components. No water vapor is applied.

A humidifying device according to a ninth aspect of the present invention provides a humidifying rotor, a humidifying passage passing through the humidifying rotor, a humidifying fan provided with the humidifying passage, a humidifying passage passing through the humidifying rotor, and a humidifying passage. A humidifying fan, provided with heating means for heating the air in the humidifying passage, wherein the humidifying rotor absorbs moisture from the air in the humidifying passage, while humidifying the heated air in the humidifying passage. The humidifying passage is adjacent to the humidifying passage via an outside air portion in the vicinity of the humidifying rotor.

In the humidifier having the above structure, since the humidifying passage is adjacent to the humidifying passage through the outside air portion in the vicinity of the humidifying rotor, the pressure difference between the humidifying passage and the outside air portion is reduced. The pressure difference between the humidification passage and the moisture absorption passage can be made smaller. Therefore, invasion of dry air into the humidifying passage can be reduced. Therefore, humidification efficiency can be improved.

According to a tenth aspect of the present invention, there is provided a humidifying rotor, a humidifying passage passing through the humidifying rotor, a humidifying fan provided with the humidifying passage, a humidifying passage passing through the humidifying rotor, and a humidifying passage. A humidifying fan, provided with heating means for heating the air in the humidifying passage, wherein the humidifying rotor absorbs moisture from the air in the humidifying passage, while humidifying the heated air in the humidifying passage. The humidifying fan and the humidifying fan are arranged on one side of the humidifying rotor.

In the humidifying device having the above structure, the humidifying fan and the humidifying fan are arranged on the same side of the humidifying rotor. The overall dimensions of the humidifier in the axial direction are reduced.

The humidifying apparatus according to the eleventh aspect of the present invention is the humidifying apparatus according to the ninth aspect.
Wherein the humidifying fan is opposed to a passage portion of the humidifying passage via a humidifying rotor, but not to an outside air portion.

[0027] In the humidifying device having the above structure, the humidifying fan faces the passage of the humidifying passage via the humidifying rotor.
It does not face the outside air at all. Therefore, even if the outside air flows from the outside air portion into the passage portion of the humidification passage, the outside air does not pass through the humidification rotor directly and does not flow into the humidification fan without passing through the passage portion. Therefore, the amount of outside air directly entering the humidifying fan from the outside air portion can be reduced, and more air heated by the heater can be passed through the humidification rotor, thereby improving the humidification efficiency.

[0028]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

As shown in FIG. 1, this humidifier has a disk-shaped humidifier rotor 12 disposed in a casing 10. This humidifying rotor 12 is made of silica gel, zeolite,
An adsorbent such as alumina is formed into a honeycomb shape or a multi-porous shape, for example, and is rotated around a shaft 12a by a motor (not shown). Further, the casing 10 is partitioned by a partition plate 11 into a humidifying rotor 12.
The humidifying passage 13 and the humidifying passage 15 passing through the respective parts are formed.

A moisture absorbing fan motor 14 is provided downstream of the humidifying rotor 12 and below the humidifying rotor 12 in the moisture absorbing passage 13 so as to suck and flow air as shown by an arrow A. This moisture absorption side fan motor 14
Although not shown, a moisture absorbing fan (referred to as a moisture absorbing fan in the sense of a fan on the moisture absorbing passage side) and a motor for driving the moisture absorbing fan are integrally formed. Humidifying rotor 12
Absorbs moisture (adsorbs moisture) from the air flowing through the moisture absorption passage 13 in the direction of arrow A. In the moisture absorption passage 13, the pressure at the point S on the upstream side of the humidification rotor 12 is about 0 mm water column, and the negative pressure at the point M on the downstream side of the humidification rotor 12 is about -7 mm water column.

On the other hand, the humidification rotor 12 of the humidification passage 15
A humidification-side fan motor 17 is provided further downstream and below the humidification rotor 12 so as to suck and flow air as shown by an arrow B. This humidifying side fan motor 1
Although not shown, a humidifying fan (referred to as a humidifying fan on the side of the humidifying passage) and a motor for driving the humidifying fan are integrally formed. A heater 16 as an example of a heating means is provided in a portion of the humidification passage 15 above the humidification rotor 12, and when air heated to 100 ° C. or higher passes through the humidification rotor 12, (Humidifying rotor 1
2 desorbs moisture). Humidifying passage 1
5 flows through the passage 1 on the upstream side of the heater 16.
5u and the passage 15d on the downstream side pass through the humidification rotor 12 twice, and the upward air flow Bu that passes first collects heat from the humidification rotor 12, recovers this heat, and then further heats the heater 16 to 100 ° C. The second downward heated airflow Bd that is heated as described above absorbs moisture from the humidifying rotor 12.
That is, as shown in FIGS.
Rotating in the direction indicated by the arrow R, a portion 12A facing the moisture absorbing passage 13, a portion 12Bd facing the passage portion 15d of the humidifying passage 15 downward, and a passage portion 1 of the humidifying passage 15 upward.
The portion 12Bu facing 5u moves sequentially. FIG.
As shown in FIG. 3, the moisture adsorbed by the humidification rotor 12 from the air A in the moisture absorption passage 13 is desorbed by the air Bd to the lower side of the humidification passage 15 heated to 100 ° C. or higher by the heater 16, and this air Bd Is humidified.

The humidified air Bd is shown in FIG.
Is drawn by the humidification side fan motor 17 shown in FIG.
At the inlet of the water column so as to have a positive pressure of 50 to 80 mm water column, and supplied to the room from an indoor unit (not shown). Since this humidifier is installed on an outdoor unit (not shown),
The pipe 19 connected to the indoor unit is considerably long. In the humidification passage 15, the negative pressure at the point L on the upstream side of the humidification rotor 12 is about −3 mm water column, and the negative pressure at the point N on the downstream side of the humidification rotor 12 is about −6 mm water column.

On the other hand, as shown in FIGS. 2 and 3, the above-mentioned water is desorbed and the air Bu to be humidified is supplied to the portion 12Bu of the humidification rotor 12 heated by the heated air.
Through the heated portion 12Bu.
To preheat. Also, this preheating is
In other words, since the portion 12Bu of the humidifying rotor 12 is cooled by the air Bu before facing the moisture absorbing passage 13, the humidifying rotor 12 can sufficiently absorb moisture in the moisture absorbing passage 13.

Since the flow of the air Bu and the flow of the air Bd are countercurrent, the direction of the thermal gradient of the flow of the air Bu and the direction of the thermal gradient in the thickness direction of the humidifying rotor 12 become the same. The flow of the air Bu can efficiently collect heat from the humidifying rotor 12.

As shown in FIG. 1, a hole 21 is provided at the bottom of the motor case of the humidifying side fan motor 17 so that water droplets condensed in the case are discharged from the hole 21. . Therefore, the motor does not fail. Further, generation of abnormal noise and deterioration of parts due to water are eliminated. Further, a protective cover 22 is provided in the vicinity of the hole 21 of the case, so that even if water vapor blows out from the hole 21, the protective cover 22 blocks the water and other parts do not receive the water vapor.

In FIG. 1, reference numerals 31, 32 and 33 are partition walls.

In the humidifier having the above structure, the portion of the humidifying rotor 12 located in the moisture absorbing passage 13 absorbs moisture from the air in the moisture absorbing passage 13 and the humidifying rotor 1 having absorbed the moisture.
The air B heated to 100 ° C. or higher by the heater 16 in the passage 15 d below the humidifying passage 15
The moisture is desorbed by d (air Bd absorbs moisture). In this way, moisture absorbed from the humidification rotor 12, that is, the humidified air Bd is absorbed by the humidification side fan motor 17 at the inlet of the pipe 19 so as to overcome the resistance of the long pipe 19 to the indoor unit. It is blown out to a positive pressure of 80 mm.

The above water is desorbed and heated air Bd
When the portion of the humidification rotor 12 heated by the heater is in the passage 15u above the humidification passage 15, the air Bu to be humidified flowing through the passage 15u is preheated. The preheated air Bu is heated by the heater 16, becomes a downward air flow Bd, is supplied to the humidification rotor 12, and is humidified. Thus, the heated humidifying rotor 1
Since the air Bu is preheated using the heat of the heater 2, the heater 1
6, the heater 16 can be reduced in size, and energy saving can be achieved.

The humidification-side fan motor 14 and the humidification-side fan motor 19 are both located downstream of the humidification rotor 12 and suck air.
In the vicinity of 2, the air pressure is negative or about zero. That is, in the moisture absorption passage 13, the pressure at the point S below the humidification rotor 12 is about 0 mm water column, and the pressure at the point M above the humidification rotor 12 is -7 mm water column.
In the humidification passage 15, the pressure at the point L above the humidification rotor 12 is a −3 mm water column, and the pressure at the point N below the humidification rotor 12 is a −6 mm water column. Therefore, the pressure difference between the point L and the point M on the upper side of the humidification rotor 12 is -3 mm water column-(-7 mm water column) = 4 mm water column, and is slight. Therefore, there is little air leakage from the humidification passage 15 to the moisture absorption passage 13 passing between the point L and the point M. The pressure difference between the point S and the point N on the lower side of the humidification rotor 12 is 0 mm water column − (− 6 mm
(Water column) = 6 mm water column, which is slight. Therefore, there is little air leakage from the moisture absorption passage 13 to the humidification passage 15 passing between the point S and the point N. As described above, since there is little air leakage between the moisture absorption passage 13 and the humidification passage 15, the humidification efficiency (humidification amount / input) is greatly improved. In particular, the humidification efficiency is greatly improved due to the fact that the leakage is small and the humidification rotor 12 preheats the air to be humidified.

In this embodiment, the humidification side fan motor 14 and the humidification side fan motor 17 are connected to the humidification rotor 1.
Since it is arranged on the lower side which is the same side as 2, the axial dimension of the humidifying rotor 12 of the entire humidifying device can be reduced. When the fan 6 of the humidification passage 3 is arranged on one side of the humidification rotor 2 and the fan 7 of the humidification passage 5 is arranged on the other side of the humidification rotor 2 as in the conventional example shown in FIG. The presence of fans 6 and 7 on both sides increases the overall size of the device.

FIG. 4 shows another embodiment. In the embodiment of FIG. 4, the outside air portion 55 that communicates with the outside air is formed by the walls 51 and 52 of the casing 50, and the humidification passage 13 and the humidification passage 15 do not directly communicate with each other above the humidification rotor 12. The only difference from the embodiment shown in FIG. Therefore, the same components as those in the embodiment of FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. Only different components will be described below.

In the moisture absorbing passage 13 shown in FIG. 4, the pressure at the point M above the humidifying rotor 12 is a -7 mm water column. In the humidification passage 15, the pressure at the point L above the humidification rotor 12 is a −3 mm water column. The outside air portion 55
The pressure at point Q is of course 0 mm water column. Therefore, the pressure difference between the point Q and the point L above the humidifying rotor 12 is 0 mm water column-(-3 mm water column) = 3 mm water column, which is smaller than the 4 mm water column in the embodiment of FIG.
As described above, since the pressure difference between the point Q of the outside air portion 55 and the point L of the humidification passage 15 is as small as 3 mm water column, the amount of air that enters the humidification passage 15 from the outside air portion 55 is small. Moreover, since the pressure of the outside air portion 55 is higher than the pressure of the humidification passage 15 near the humidification rotor 12, the heated air does not leak from the humidification passage 15. Therefore, the humidification efficiency is greatly improved. In particular, the humidification efficiency is greatly improved due to the fact that the leakage is small and the humidification rotor 12 preheats the air to be humidified. In addition, since the humidifying side and the moisture absorbing side are not influenced by the pressure fluctuation of the other party, a constant flow can be maintained in each passage, and the performance is stabilized.

The embodiment shown in FIG. 6 is different from the embodiment shown in FIG. 4 in the arrangement of the humidifying side fan motor 57, and the other points are the same as the embodiment shown in FIG. Therefore, the same components as those in the embodiment of FIG. 4 are denoted by the same reference numerals, and description thereof will be omitted. Only different components will be described below.

In the embodiment shown in FIG. 6, the humidification-side fan motor 57 faces the upper passage portion 15 d of the humidification passage 15 via the humidification rotor 12, and does not face the outside air portion 55 at all. Therefore, even if the outside air flowing from the point Q of the outside air portion 55 flows into the passage portion 15d of the humidification passage 15 above the humidification rotor 12, the outside air passes directly through the humidification rotor 12 without passing through the passage portion 15d. , Does not flow directly into the humidifying fan motor 57. Therefore, the outside air portion 5
5 can be reduced, and the air heated by the heater 16 can pass through the humidification rotor 12 more, thereby improving the humidification efficiency.

In the above-described embodiment, the heater 16 is used as the heating means. Instead of the heater 16, another heating means such as the exhaust heat of a compressor of an outdoor unit or a microwave is used. Is also good.

Further, in the above embodiment, the humidifier is provided on the outdoor unit of the air conditioner to blow out the humidified air from the indoor unit. However, the humidifier can be used alone. It is.

In the above embodiment, the fan motors 14 and 17 in which the fan and the motor are integrated are used.
A separate fan and motor may be used.

In the above-described embodiment, an example has been described in which the humidifying fan motor 17 and the humidifying motor fan motor 14 are provided in the humidifying passage 15 and the humidifying passage 13 downstream of the humidifying rotor 12, respectively. However, even when the humidification-side fan motor and the humidification-side fan motor are provided on the upstream side of the humidification rotor, the provision of the outside air portion makes it possible to prevent both the humidification-side and the moisture-absorption side from being influenced by the pressure fluctuation of the other side, and to allow each passage A constant flow can be maintained in the inside, and the performance can be stabilized. Further, even if the humidifying side fan motor and the humidifying side fan motor are provided on the upstream side and one side of the humidifying rotor, the humidifying device can be downsized.

[0049]

As is clear from the above, according to the first aspect of the present invention, the humidifying fan and the humidifying fan are provided on the downstream side of the humidifying rotor. Due to the negative pressure, the pressure difference between the air in the humidifying passage and the air in the humidifying passage near the end face of the humidifying rotor or between the air in the humidifying passage and the outside air is small, and air leakage in the humidifying passage is caused. Alternatively, the intrusion of outside air into the humidification passage can be reduced, and therefore, the humidification efficiency can be improved.

According to the second aspect of the present invention, the humidifying passage is directly adjacent to the humidifying passage near the humidifying rotor. However, as in the first aspect of the present invention, the humidifying passage is located near the end face of the humidifying rotor. Since the pressure difference between the air and the air in the humidifying passage is small, even if the humidifying passage is directly adjacent to the humidifying passage near the humidifying rotor, air leakage in the humidifying passage can be reduced.

According to the third aspect of the present invention, since the humidifying passage is adjacent to the humidifying passage through the outside air portion in the vicinity of the humidifying rotor, the pressure difference between the humidifying passage and the outside air portion is reduced.
It can be smaller than the pressure difference between the humidifying passage and the moisture absorbing passage,
Therefore, invasion of outside air into the humidifying passage can be reduced. Further, since the humidifying side and the moisture absorbing side are not influenced by the pressure fluctuation of the other party, a constant flow can be maintained in each passage, and the performance is stabilized.

According to the fourth aspect of the present invention, after the air to be humidified is pre-heated through the humidifying rotor portion where the moisture is desorbed by the air heated by the heating means, the pre-heated air is heated by the heating means. Therefore, the load on the heating means can be reduced, the heating means can be downsized, and energy saving can be achieved. In particular, the leakage from the humidifying passage or the leakage to the humidifying passage is small, and this preheating is combined. What
Humidifying efficiency can be greatly improved.

According to the fifth aspect of the present invention, since the air leakage between the humidifying passage and the humidifying passage is small and the humidifying fan and the humidifying fan are arranged on one side of the humidifying rotor, the humidifying efficiency is improved. And a small and compact humidifier can be provided.

According to the sixth aspect of the present invention, since the heater is disposed above the humidifying rotor, even if dew condensation occurs on the humidifying rotor or the like, the heater does not leak.

According to the seventh aspect of the present invention, since the hole is provided at the bottom of the case of the motor for driving the humidifying fan, water droplets condensed in the case of the motor of the humidifying fan can be discharged from the hole.

According to the eighth aspect of the present invention, since the protective cover is provided near the hole of the case of the motor of the humidifying fan, even if water vapor blows out from the hole, it is blocked by the protective cover and is blocked by other parts. No water vapor is applied.

According to the ninth aspect of the present invention, since the humidifying passage is adjacent to the humidifying passage via the outside air portion in the vicinity of the humidifying rotor, the pressure difference between the humidifying passage and the outside air portion is reduced.
It can be smaller than the pressure difference between the humidifying passage and the moisture absorbing passage,
Therefore, it is possible to reduce the leakage of air from the humidification passage or the intrusion of outside air into the humidification passage, and to improve the humidification efficiency. Further, since the humidifying side and the moisture absorbing side are not influenced by the pressure fluctuation of the other party, a constant flow can be maintained in each passage, and the performance is stabilized.

According to the tenth aspect of the present invention, since the humidifying fan and the humidifying fan are arranged on the same side of the humidifying rotor, the size of the entire humidifying device in the axial direction of the humidifying rotor can be reduced.

According to the eleventh aspect of the present invention, the humidifying fan faces the passage portion of the humidifying passage via the humidifying rotor, but does not face the outside air portion. It does not pass through and enter the humidification fan. Therefore, the amount of air entering the humidifying fan from the outside air portion can be reduced, and more air heated by the heater can be passed through the humidifying rotor, thereby improving the humidifying efficiency.

[Brief description of the drawings]

FIG. 1 is a schematic view of a humidifier according to an embodiment of the present invention.

FIG. 2 is a plan view of the humidifying rotor in the embodiment.

FIG. 3 is a schematic view illustrating the operation of the humidification rotor.

FIG. 4 is a schematic diagram of a humidifying device according to another embodiment.

FIG. 5 is a schematic view of a conventional humidifier.

FIG. 6 is a schematic diagram of a humidifier according to another embodiment.

[Explanation of symbols]

Reference Signs List 12 humidifying rotor 13 humidifying passage 15 humidifying passage 16 heater 14 humidifying side fan motor 17, 57 humidifying side fan motor 21 hole 22 protective cover

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Kozo Yoshinaga 1000-2 Oya, Okamotocho, Kusatsu-shi, Shiga F-term in Daikin Industries, Ltd. Shiga Works (reference) 3L053 BC09 3L055 BA01 CA04 DA05

Claims (11)

[Claims] 1. A humidifying rotor (12), a moisture absorbing passage (13) passing through the humidifying rotor (12), a moisture absorbing fan provided in the moisture absorbing passage (13), and the humidifying rotor (1).
2) and a humidifying passage (15) passing through the humidifying passage (1).
5) a humidification fan provided in the humidification passage (15) and a heating means (16) for heating the air in the humidification passage (15), and the humidification rotor (12) absorbs moisture from the air in the moisture absorption passage (13), In a humidifying device for humidifying the heated air in the humidifying passage (15), the humidifying fan is provided in a humidifying passage (13) downstream of the humidifying rotor (12), and the humidifying fan is connected to the humidifying rotor (13). (12) A humidifying device provided in a humidifying passage (15) downstream of the humidifying passage. 2. The humidifying device according to claim 1, wherein the humidifying passage (15) is directly adjacent to the humidifying passage (13) in the vicinity of the humidifying rotor (12). Humidifier. 3. The humidifying device according to claim 1, wherein the humidifying passage (15) is adjacent to the humidifying passage (13) via an outside air part (55) near the humidifying rotor (12). A humidifying device characterized in that: 4. The humidifying device according to claim 1, wherein moisture is desorbed by air in a humidifying passage heated by said heating means. A humidifying device characterized in that the air to be humidified is preheated to the portion (1), and the preheated air is heated by the heating means (16) and passed through the humidifying rotor (12). 5. The humidifying device according to claim 1, wherein the humidifying fan and the humidifying fan are arranged on one side of the humidifying rotor. apparatus. 6. The humidifying device according to claim 1, wherein a heater (1) serving as the heating means is provided in a humidifying passage (15) above the humidifying rotor (12).
6), wherein the humidifying fan is provided below the humidifying rotor (12). 7. The humidifying device according to claim 1, wherein a hole (21) is provided at a bottom of a case of a motor for driving the humidifying fan. 8. The humidifying device according to claim 7, wherein a protective cover (22) is provided near the hole (21) of the case. 9. A humidification rotor (12), a moisture absorption passage (13) passing through the humidification rotor (12), a moisture absorption fan provided in the moisture absorption passage (13), and the humidification rotor (1).
2) and a humidifying passage (15) passing through the humidifying passage (1).
5) a humidification fan provided in the humidification passage (15) and a heating means (16) for heating the air in the humidification passage (15), and the humidification rotor (12) absorbs moisture from the air in the moisture absorption passage (13), In the humidifying device for humidifying the heated air in the humidifying passage (15), the humidifying passage (15) is connected to the humidifying passage (13) in the vicinity of the humidifying rotor (12) via an outside air part (55). A humidifying device characterized by being adjacent. 10. A humidification rotor (12), a moisture absorption passage (13) passing through the humidification rotor (12), a moisture absorption fan provided in the moisture absorption passage (13), and the humidification rotor (1).
2) and a humidifying passage (15) passing through the humidifying passage (1).
5) a humidification fan provided in the humidification passage (15) and a heating means (16) for heating the air in the humidification passage (15), and the humidification rotor (12) absorbs moisture from the air in the moisture absorption passage (13), In a humidifying device for humidifying heated air in a humidifying passage (15), the humidifying fan and the humidifying fan are connected to the humidifying rotor (1).
2) A humidifying device, wherein the humidifying device is arranged on the same side. 11. The humidifying device according to claim 9,
The humidifying device, wherein the humidifying fan faces the passage portion (15d) of the humidifying passage (15) via the humidifying rotor (12), but does not face the outside air portion (55).