KR100420643B1 - Humidifier - Google Patents

Abstract

There is provided is a humidifier that has a small amount of leak of air between its humidification passage and its moisture absorption passage and has a high humidification efficiency. A moisture absorption side fan motor 14 and a humidification side fan motor 17 are provided on the downstream side of a humidifying rotor 12, by which a humidification passage 13 and a moisture absorption passage 15 have negative pressures in the vicinity of an end surface of the humidifying rotor 12. Therefore, a pressure difference between air in the humidification passage 15 and air in the moisture absorption passage 13 is small in the vicinity of the end surface of the humidifying rotor 12, by which the leak of air is a little and the humidification efficiency is improved. The moisture absorption side fan motor_14 and the humidification side fan motor 17 are arranged on the same lower side of the humidifying rotor 12, making the humidifier compact. <IMAGE>

Description

Humidifier {HUMIDIFIER}

Typically, a humidifier of the kind as shown in Fig. 5 (see Japanese Patent Application Laid-open No. Hei 8-141345) is known in the art. This humidifier has a humidifier rotor 2; The humidifier rotor 2 is composed of an adsorbent made of silica gel, zeolite or the like and is arranged in the casing 1. The moisture absorption passage 3 and the humidification passage 5 extend through the humidifier rotor 2. The humidifier rotor 2 performs a hygroscopic action in the moisture absorption passage 3 and a humidification action in the humidification passage 5. The fan 6 is provided upstream of the humidifier rotor 2 in the moisture absorption passage 3 to create an air flow as shown by arrows A and B, whereby the humidifier rotor 2 is adapted to the moisture absorption. The moisture is absorbed from the air in the passage 3. On the other hand, the fan 7 and the heater 8 are provided upstream of the humidifier rotor 2 in the humidification passage 5 to penetrate through the humidification passage 5 to carry out an air flow as shown by arrows C and D. FIG. Create. Air heated by the heater 8 while being supplied with pressure by the fan 7 in the humidification passage 5 is humidified by the humidifier rotor 2 (by absorbing moisture from the humidifier rotor 2) and It is then fed to the indoor unit through piping (not shown).

In this humidifier, the humidifier rotor 2 absorbs moisture from the air in the moisture absorption passage 3, and this moisture is discharged from the humidifier rotor 2 into the air in the humidification passage 5. This arrangement has the advantage that no specific moisture supply unit is required.

However, in the humidifier structured as described above, the fan 6 in the moisture absorption passage 3 and the fan 7 in the humidification passage 5 are arranged upstream of the humidifier rotor 2, and thus, The arrangement has the problem as mentioned below. That is, generally, a large amount of air (for example, 3 m ³ / min) flows through the moisture absorption passage 3 to enable moisture absorption from the air. The hygroscopic passage 3 has a relatively large transverse cross-sectional area and the fan 6 applies sufficient pressure to simply allow air to penetrate the humidifier rotor 2. Therefore, the pressure at the upstream point M of the humidifier rotor 2 in the moisture absorption passage 3 is about 7 mm water column pressure. On the other hand, a relatively small amount of air (eg 0.2 m ³ / min) is supplied to the humidification passage 5. The humidifying passage 5 has a relatively small cross-sectional area; The pressure at the downstream point L of the humidifier rotor 2 in the humidifying passage 5 becomes 50 to 80 mm water pressure to overcome the resistance of the long pipe leading to the indoor unit from the humidifying passage 5 side. Therefore, a problem arises in that the pressure difference between the points M and L becomes about 43 to 73 water pressure and a considerable amount of the humidified air in the humidification passage 5 leaks into the moisture absorption passage 3. The humidifier rotor 2 is rotated about the axis 2a, and therefore, with the wall 9 disposed between the point L and the point M, a gap between the wall 9 and the humidifier rotor 2 is achieved. Is generated. Due to the large pressure difference as described above, a large amount of humidified air leaks through the gap. Due to such leakage of humidified air, a decrease in humidification efficiency (humidification / input amount) is caused.

The present invention relates to, for example, a humidifier for moistening air supplied to a room, and more particularly to a humidifier for moistening air supplied by collecting moisture from the air without using a specific moisture supply unit.

1 is a schematic diagram showing a humidifier according to an embodiment of the present invention.

2 is a plan view of the humidifier rotor used in the humidifier of FIG.

3 is a schematic view for explaining the operation of the humidifier rotor.

Figure 4 is a schematic diagram showing a humidifier according to another embodiment of the present invention.

5 is a schematic view showing a conventional humidifier.

Figure 6 is a schematic diagram showing a humidifier according to another embodiment of the present invention.

Accordingly, it is an object of the present invention to provide a humidifier that reduces the amount of air leakage between the humidification passage and the moisture absorption passage and achieves high humidification efficiency.

In order to achieve the above object, according to the first aspect of the present invention, a humidifier rotor, a moisture absorption passage extending through the humidifier rotor, a moisture absorption fan arranged in the moisture absorption passage, a humidification passage extending through the humidifier rotor, A humidification fan arranged in the humidification passage, and heating means for heating air in the humidification passage, wherein the humidifier rotor absorbs moisture from the air in the moisture passage and moisture in the heated air in the humidification passage. A humidifier is provided, wherein: the humidifier is characterized in that the hygroscopic fan is arranged in the hygroscopic passage downstream of the humidifier rotor and the humidifying fan is arranged in the humidifying passage downstream of the humidifier rotor. It is done.

In the humidifier having such a structure, the hygroscopic fan and the humidifying fan are provided downstream of the humidifier rotor. The humidifying passage and the hygroscopic passage have a negative pressure near the end surface of the humidifier rotor and do not have a static pressure as high as that of the humidifying air to which pressure is applied at the outlet side of the humidifying fan. Therefore, the pressure difference between the air in the humidifying passage and the air in the humidifying passage or the pressure difference between the air in the humidifying passage and the outdoor air is kept at a small value near the end surface of the humidifier rotor, and thus the leakage of air from the humidifying passage. Alternatively, the inflow of outdoor air into the humidifying passage is reduced. Therefore, the humidification efficiency is improved.

In one embodiment, the humidifying passage is in direct proximity to the hygroscopic passage near the humidifier rotor.

In this embodiment, the pressure difference between the air in the humidification passage and the air in the moisture absorption passage is kept at a small value near the end surface of the humidifier rotor. Therefore, even if the humidifying passage is in close proximity to the hygroscopic passage near the humidifier rotor, the leakage of air from the humidifying passage is reduced.

In another embodiment, the humidification passage is proximate to the moisture absorption passage via an outdoor air portion near the humidifier rotor.

In this embodiment, the humidification passage is proximate to the moisture absorption passage via the outdoor air portion near the humidifier rotor, and therefore, the pressure difference between the air in the humidification passage and the air in the outdoor air portion is dependent on the humidification passage. It may be maintained at a value smaller than the pressure difference between the moisture absorption passages. Thus, leakage between the outdoor air portion and the humidifying passage can be reduced. In addition, neither the humidification side nor the moisture absorption side is affected by the pressure fluctuations on the counterpart side. Thus, a constant flow can be maintained in each passage, and the performance of the humidifier is stabilized.

In another embodiment, the part of the humidifier rotor whose moisture is deodorized by the air heated by the heating means in the humidifying passage is preheated by the flowing air that is humidified through the portion, and the preheated air is heated It is heated by means and then passes through the humidifier rotor.

In this embodiment, the part of the humidifier rotor whose moisture is deodorized by the air heated by the heating means is preheated by the flowing air that is humidified while passing through the portion, and the preheated air is then heated by the heating means. Heated. Therefore, the load of the heating means is reduced, whereby the heating means can have a concise structure, and energy saving is possible. In particular, by the combined action of the above arrangement and the preheating just mentioned so that leakage of air from the humidifying passage or inflow of the air into the humidifying passage is reduced, the humidification efficiency of the humidifier is significantly improved.

In another embodiment, the moisture absorption fan and the humidification fan are arranged on one and the same side of the humidifier rotor.

In this embodiment, the moisture absorption fan and the humidification fan are arranged on one and the same side of the humidifier rotor. Therefore, the size of the entire humidifier in the axial direction of the humidifier rotor becomes smaller than when the hygroscopic fan and the humidifying fan are arranged on both sides of the humidifier rotor. Thus, a humidifier having a small air leakage amount, high humidification efficiency and a compact structure body is provided.

In another embodiment, the heater serving as the heating means is arranged in the humidifying passage at the upper side of the humidifier rotor and the humidifying fan is arranged at the lower side of the humidifier rotor.

In this embodiment, the heater is arranged on the upper side of the humidifier rotor; Therefore, even if dew condensation occurs in the humidifier rotor or the like, the heater does not cause a short circuit. Air heated by the heater is sucked by the humidifying fan toward the lower side of the humidifier rotor.

In another embodiment, the motor for driving the humidifying fan has a casing, and a hole is formed in the bottom portion of the casing.

In this embodiment, water droplets generated through dew condensation in the casing of the motor of the humidifying fan are discharged through the holes of the casing. Therefore, the failure of the motor is not caused. This arrangement also excludes the possibility of noise generation and component deterioration due to moisture.

In another embodiment, a protective cover is provided near the opening of the casing.

In this embodiment, a protective cover is provided near the opening of the casing of the motor of the humidifying fan. Therefore, when steam is ejected from the hole, the steam is blocked by the protective cover so that it is not sprayed onto other components.

According to a second aspect of the present invention, a humidifier rotor, a moisture absorption passage extending through the humidifier rotor, a moisture absorption fan arranged in the moisture absorption passage, a humidification passage extending through the humidifier rotor, a humidification fan arranged in the humidification passage And a heating means for heating the air in the humidification passage, wherein the humidifier rotor absorbs moisture from the air in the moisture passage and applies moisture to the heated air in the humidification passage. The humidifier is characterized in that the humidification passage is proximate to the moisture absorption passage via an outdoor air portion near the humidifier rotor.

In the humidifier having such a structure, the humidifying passage is proximate to the hygroscopic passage via the outdoor air portion near the humidifier rotor. Therefore, the pressure difference between the humidification passage and the outdoor air portion can be maintained at a value smaller than the pressure difference between the humidification passage and the moisture absorption passage. Thus, the inflow of dry air into the humidifying passage can be reduced. Accordingly, the humidification efficiency can be improved.

According to a third aspect of the present invention, a humidifier rotor, a moisture absorption passage extending through the humidifier rotor, a moisture absorption fan arranged in the moisture absorption passage, a humidification passage extending through the humidifier rotor, a humidification fan arranged in the humidification passage And a heating means for heating the air in the humidification passage, wherein the humidifier rotor absorbs moisture from the air in the moisture absorption passage and applies moisture to the heated air in the humidification passage. This humidifier is characterized in that the hygroscopic fan and the humidifying fan are arranged on one and the same side of the humidifier rotor.

In the humidifier having such a structure, the hygroscopic fan and the humidifying fan are arranged on one and the same side of the humidifier rotor. Therefore, the size of the entire humidifier in the axial direction of the humidifier rotor becomes smaller than when the hygroscopic fan and the humidifying fan are arranged on both sides of the humidifier rotor.

In another embodiment, the humidifying fan is directed toward the passage portion of the humidification passageway and not to the outdoor air portion via the humidifier rotor.

In this embodiment, the humidification fan is directed towards the passage portion of the humidification passageway via the humidifier rotor and not entirely towards the outdoor air portion. Therefore, even if outdoor air flows from the outdoor air portion to the passage portion of the humidifying passage, the outdoor air does not flow directly into the humidifying fan through the humidifier rotor without passing through the passage portion. Thus, the amount of outdoor air directly introduced into the humidification fan from the outdoor air portion can be reduced, so that a greater amount of air heated by the heater flows through the humidifier rotor, thereby increasing the humidification efficiency. Is improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the humidifier according to the invention has a disc humidifier rotor 12 arranged in a casing 10. The humidifier rotor 12 is constituted by molding an adsorbent made of silica gel, zeolite, alumina, or the like, for example, in a honeycomb form or in the form of porous multiparticulates, and is rotated about an axis 12a by a motor (not shown). The casing 10 is partitioned by a partition plate 11 to provide a moisture absorption passage 13 and a humidification passage 15, and the moisture absorption passage 13 and the humidification passage 15 are humidifier rotors 12. Extends through portions of the.

A moisture absorption side fan motor 14 is provided in the moisture absorption passage 13 on the downstream side of the humidifier rotor 12 and on the lower side of the humidifier rotor 12 to suck the air as shown by arrow A. Create a flow. Although not shown in the drawing, the moisture absorption side fan motor 14 is composed of a moisture absorption fan (referred to as a moisture absorption fan in the sense of a fan disposed on the moisture absorption path side) and a motor for driving the moisture absorption fan. Are integrated to form one unit. The humidifier rotor 12 absorbs moisture (moisture) from air flowing through the moisture absorption passage 13 in the direction of arrow A. FIG. In the moisture absorption passage 13, the pressure at the upstream side S of the humidifier rotor 12 is about 0 mm water pressure, and the negative pressure at the downstream side M of the humidifier rotor 12 is about -7 mm water pressure. Becomes

On the other hand, a humidifying side fan motor 17 is provided in the humidifying passage 15 on the downstream side of the humidifier rotor 12 and on the lower side of the humidifier rotor 12 to suck in air as shown by arrow B. FIG. Thereby creating an air flow. Although not shown in the drawings, the humidifying side fan motor 17 is constituted by a humidifying fan (referred to as a humidifying fan in the sense of a fan disposed on the humidifying passage side) and a motor for driving the humidifying fan. It is integrated to form one unit. A heater 16 serving as one embodiment of the heating means is provided in the upper portion of the humidifier rotor 12 in the humidification passage 15, and is thus heated by the heater 16 to provide a temperature of 100 ° C. or more. The air having is humidified by the humidifier rotor 12 (by absorbing moisture from the humidifier rotor 12) while passing through the humidifier rotor 12. Air flowing along the humidification passage 15 passes through the passage portion 15u provided on the upstream side of the heater 16 and the passage portion 15d provided on the downstream side of the heater 16, thereby providing a humidifier rotor ( 12) penetrate twice. The upward air flow rate Bu, which first passes through the humidifier rotor 12, collects heat from the humidifier rotor 12, collects heat in this way, and is then further heated to a temperature of 100 ° C. or higher by the heater 16. The downward air flow rate Bd absorbs moisture from the humidifier rotor 12. That is, as shown in FIGS. 2 and 3, the humidifier rotor 12 is rotated in the direction indicated by the arrow R, the portion 12A facing the moisture absorption passage 13 and the downward passage of the humidification passage 15. The portion 12Bd facing the portion 15d and the portion 12Bu facing the upward passage portion 15u of the humidifying passage 15 are continuously moved. As shown in FIG. 3, the moisture absorbed by the humidifier rotor 12 from the air A in the moisture absorption passage 13 is heated by the heater 16 and has a temperature of 100 ° C. or higher, while the humidification passage 15 Is deodorized by air Bd directed to the lower side of the &lt; RTI ID = 0.0 &gt;), &lt; / RTI &gt;

The air Bd to be humidified as described above is sucked by the humidifying side fan motor 17 shown in FIG. 1, and 50 to 50 at the inlet of the pipe 19 to overcome the resistance of the long pipe 19. Pressure is provided to have a positive pressure corresponding to 80 mm water pressure, and is supplied to the room through an indoor unit (not shown). The humidifier according to the present invention is installed on an outdoor unit (not shown), and therefore, the pipe 19 connected to the indoor unit increases in length. In the humidification passage 15, the negative pressure at the upstream point L of the humidifier rotor 12 is about -3 mm water pressure, and the negative pressure at the downstream point N of the humidifier rotor 12 is about -6 mm water order. It becomes pressure.

On the other hand, as shown in FIGS. 2 and 3, the upward air flow rate Bu to be humidified passes through the portion 12Bu of the humidifier rotor 12 and is heated by heated air and dehumidified by the humidifier rotor. 12 preheats air Bu in the heated portion 12Bu. In other respects, this preheating means cooling the humidifier rotor 12 part 12Bu by air Bu before the part 12Bu is directed to the moisture absorption passage 13, and the humidifier rotor 12. ) Can sufficiently absorb moisture in the moisture absorption passage 13.

The flow of air Bu and the flow of air Bd are opposite in direction, and the temperature gradient in the flow of air Bu and the temperature gradient in the thickness direction of the humidifier rotor 12 are the same, and accordingly The air flow rate Bu can efficiently collect heat from the humidifier rotor 12.

As shown in FIG. 1, the motor casing of the humidifying side fan motor 17 has a hole 21 formed at the bottom thereof so that water droplets condensed in the casing can be discharged through the hole 21. . By this arrangement, the motor does not fail. This arrangement also eliminates the possibility of component deterioration due to noise generation and moisture. In addition, the casing is provided with a protective cover 22 in the vicinity of the hole 21; Thus, when steam is blown out of the hole 21, this steam is blocked by the protective cover 22 and is not sprayed onto the other components.

Reference numerals 31, 32 and 33 denote partition walls in FIG.

In the humidifier having the above configuration, the portion of the humidifier rotor 12 disposed in the moisture absorption passage 13 adsorbs moisture from the air in the moisture absorption passage 13. In the portion of the humidifier rotor 12 that absorbs moisture, the moisture is air heated to a temperature of 100 ° C. or more by the heater 16 in the passage portion 15d facing the lower side of the humidification passage 15 ( Bd) is deodorized (air Bd absorbs moisture). As described above, the air Bd that absorbs moisture from the humidifier rotor 12, that is, the humidified air Bd, is used to overcome the resistance of the long pipe 19 extending to the indoor unit. ) Is blown out by the humidifying side fan motor 17 so as to have a static pressure corresponding to a water pressure of 50 to 80 mm at the inlet of the.

The portion of the humidifier rotor 12 heated by the heated air Bd and desorbed therein is deodorized when placed in the passage portion 15u facing the upper side of the humidifying passage 15. The humidified air Bu flowing through the passage portion 15u is preheated. The preheated air Bu is heated by the heater 16 and supplied to the humidifier rotor 12 to a downward air flow rate Bd to be humidified. As described above, the air Bu is preheated using the heat of the heated humidifier rotor 12, and therefore, the heater 16 can be reduced in its load, can have a concise structure, and can save energy. do.

The humidifying side fan motor 14 and the humidifying side fan motor 17 suck air in a state arranged downstream of the humidifier rotor 12, and therefore the air is negative pressure or near zero in the vicinity of the humidifier rotor 12. Have zero pressure. That is, in the moisture absorption passage 13, the pressure at the lower side point S of the humidifier rotor 12 becomes approximately 0 mm water column pressure, and the pressure at the upper side point M of the humidifier rotor 12 is -7 mm water column. It becomes pressure. In the humidification passage 15, the pressure at the upper side point L of the humidifier rotor 12 is -3 mm water column pressure, and the pressure at the lower side point N of the humidifier rotor 12 is -6 mm water column pressure. do. Therefore, the differential pressure between the point L and the point M at the upper side of the humidifier rotor 12 is 4 mm (-3 mm-(-7 mm)), which is a small value. Therefore, the leakage of air passing through the point L and the point M from the humidification passage 15 to the moisture absorption passage 13 becomes small. In addition, the pressure difference between the point S and the point N at the lower side of the humidifier rotor 12 becomes 6 mm (0 mm-(-6 mm)), which is a small value. Therefore, the leakage of air passing through the point S and the point N from the moisture absorption passage 13 to the humidification passage 15 becomes small.

As described above, the leakage of air between the moisture absorption passage 13 and the humidification passage 15 becomes small, and therefore the humidification efficiency (humidification / input amount) is significantly improved. In particular, by the cooperative effect of this small amount of leakage and the preheating of the air to be humidified by the humidifier rotor 12, the humidification efficiency is greatly improved.

In this embodiment, the hygroscopic side fan motor 14 and the humidifying side fan motor 17 are arranged on the same side with respect to the lower side, or the humidifier rotor 12, and therefore, of the humidifier rotor 12 of the entire humidifier. The magnitude in the axial direction can be reduced. In the example according to the prior art shown in FIG. 5, if the fan 6 of the moisture absorption passage 3 is arranged on one side of the humidifier rotor 2 and the fan 7 of the humidification passage 5 is the humidifier rotor 2. When arranged on the other side of), the size of the entire humidifier is increased because of the presence of fans 6 and 7 on both sides of the humidifier rotor 2.

4 shows another embodiment of the present invention. In the embodiment shown in FIG. 4, the outdoor air portion 55 in communication with the outdoor air is formed by the walls 51 and 52 of the casing 50 and the hygroscopic passage 13 and the humidifying passage 15 are directly connected to each other. It differs from the embodiment shown in FIG. 1 in that it communicates with each other via the outdoor air portion 55 located above the humidifier rotor 12 rather than communicating with each other. Therefore, the same components as the components of the embodiment shown in FIG. 1 are given the same reference numerals, and further description thereof will be omitted, and only different components will be described below.

In the moisture absorption passage 13 shown in FIG. 4, the pressure at the upper side point M of the humidifier rotor 12 is -7 mm water column pressure. In the humidification passage 15, the pressure at the upper side point L of the humidifier rotor 12 is -3 mm water column pressure. The pressure at point Q in the outdoor air portion 55 is of course 0 mm water pressure. Therefore, the pressure difference between the point Q and the point L at the upper side of the humidifier rotor 12 becomes the water pressure of 3 mm (0 mm-(-3 mm)), which is the value in the embodiment shown in FIG. It is smaller than 4mm water column pressure. As described above, the pressure difference between the point Q of the outdoor air portion 55 and the point L of the humidifier rotor 12 becomes the 3 mm water pressure, and therefore, flows from the outdoor air portion 55 into the humidifying passage 15. The amount of air that becomes becomes small. In addition, the pressure in the outdoor air portion 55 is higher than the pressure near the humidifier rotor 12 in the humidification passage 15, and therefore, the heated air does not leak from the humidification passage 15. Therefore, the humidification efficiency is remarkably improved. By the cooperative effect of the small amount of leakage and the preheating of the air to be humidified by the humidifier rotor 12, the humidification efficiency is greatly improved. In addition, neither the humidification side nor the moisture absorption side is affected by the pressure fluctuations of the counterpart side. Therefore, a constant flow can be maintained in each passage, and the performance of the entire humidifier 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 in other respects, the embodiment shown in FIG. Therefore, the same components as those of the embodiment shown in FIG. 4 are given the same reference numerals, and further description thereof will be omitted, and only different components will be described below.

In the embodiment shown in FIG. 6, the humidifying side fan motor 57 is directed toward the passage portion 15d on the upper side of the humidifying passage 15 via the humidifier rotor 12 and is entirely directed to the outdoor air portion 55. It will not face. Therefore, even if outdoor air flowing through the point Q of the outdoor air portion 55 flows into the passage portion 15d of the humidification passage 15 from the upper side of the humidifier rotor 12, the outdoor air is supplied to the humidifier rotor 12. ) Does not flow directly through the humidifying side fan motor 17. Therefore, the amount of air introduced from the outdoor air portion 55 can be reduced, and the increased amount of air heated by the heater 16 penetrates the humidifier rotor 12, thereby improving the humidification efficiency. .

In the above embodiments, the heater 16 is used as the heating means, but it is also possible to use the exhaust heat of the compressor constituting the outdoor unit or to use other heating means such as microwaves instead of the heater 16.

In the above embodiments, the humidifier is installed in the outdoor unit of the air conditioner and the humidified air is discharged from the indoor unit, but it is also possible to use the humidifier alone.

In the above embodiments, the fan motors 14 and 17 obtained by integrating the fan and the motor have been used, but it is also possible to use a fan and a motor having separate bodies, respectively.

In the above embodiments, the humidification side fan motor 17 and the moisture absorption side fan motor 14 are respectively provided in the humidification passage 15 and the moisture absorption passage 13 and disposed downstream of the humidifier rotor 12. An example has been described. However, even when the humidification side fan motor and the moisture absorption side fan motor are provided upstream of the humidifier rotor, by installing the outdoor air portion, it is possible to prevent the humidification side and the moisture absorption side from being affected by the pressure variation of the counterpart. It is possible to maintain a constant flow in each passage and to stabilize the performance of the entire humidifier. Even when the humidifying side fan motor and the humidifying side fan motor are provided upstream of the humidifier rotor, the humidifier can have a concise structure.

Claims (11)

A humidifier rotor, a hygroscopic passage extending through the humidifier rotor, a hygroscopic fan arranged in the hygroscopic passage, a humidifying passage extending through the humidifier rotor, a humidifying fan arranged in the humidifying passage, and heating the air in the humidifying passage. Wherein the humidifier rotor absorbs moisture from the air in the moisture absorption passage and imparts moisture to the heated air in the humidification passage. The hygroscopic fan is arranged in the humidification passage on the downstream side of the humidifier rotor, the humidification fan is arranged in the humidification passage on the downstream side of the humidifier rotor, And the humidification passage is proximate to the moisture absorption passage via an outdoor air portion near the humidifier rotor. delete delete The method of claim 1, A portion of the humidifier rotor in which the moisture is deodorized by the air heated by the heating means in the humidifying passage is preheated by the flowing air humidified while passing through the portion, and the preheated air is heated by the heating means and then the Humidifier characterized in that to penetrate the humidifier rotor. The method of claim 1, And the humidifying fan and the humidifying fan are arranged on one and the same side of the humidifier rotor. The method of claim 1, And a heater acting as said heating means is arranged in said humidifying passage at the upper side of said humidifier rotor, and said humidifying fan is arranged at the lower side of said humidifier rotor. The method of claim 1, The motor for driving the humidification fan has a casing, characterized in that the bottom portion of the casing is formed with a hole. The method of claim 7, wherein A humidifier, characterized in that a protective cover is provided near the opening of the casing. A humidifier rotor, a hygroscopic passage extending through the humidifier rotor, a hygroscopic fan arranged in the hygroscopic passage, a humidifying passage extending through the humidifier rotor, a humidifying fan arranged in the humidifying passage, and heating the air in the humidifying passage. Wherein the humidifier rotor absorbs moisture from the air in the moisture absorption passage and imparts moisture to the heated air in the humidification passage. And the humidifying passage is proximate to the hygroscopic passage via an outdoor air portion near the humidifier rotor. delete The method of claim 9, And the humidifier fan faces the passage portion of the humidification passageway via the humidifier rotor and does not face the outdoor air portion.