JP2006010307A - Humidifier, and humidifying method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidifying method, and a humidifier which is a humidifier humidifying a room by water contents trapped by an adsorbent, capable of reducing leakage to the room of odor contents trapped along with the moisture contents. <P>SOLUTION: The humidifier is provided with an air supply passage 1 supplying air of outdoors 6, an exhaust passage 2 exhausting air of the room 7, an adsorbent holding mechanism 3 positioning one parts of the adsorbent 4 respectively in the air supply passage 1 and the exhaust passage 2, and a heating means 51 arranged in the air supply passage 1. The adsorbent 4 is an adsorbent desorbing moisture contents by being heated to a temperature T1 or higher and desorbing odorous contents by being heated to a temperature T2 or more that is higher than the temperature T1. In humidifying operation, moisture contents are adsorbed in the exhaust passage 2, and moisture contents substantially not accompanied by odor are desorbed in the air supply passage 1. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a humidifying device and a humidifying method, and more particularly to a humidifying device that humidifies a room with moisture trapped by an adsorbent, and leakage of odor components trapped with the moisture by the adsorbent into the chamber. The present invention relates to a humidifier that can reduce the humidity and a humidification method using the humidifier.

In recent years, a technique for humidifying indoor air by using the adsorption and desorption functions of an adsorbent has been proposed. For example, a humidifier that adsorbs moisture from an outdoor air to an adsorbent and supplies the adsorbed moisture to a room is disclosed as a “air conditioner with a dehumidifying / humidifying function” (Patent Document 1). A humidifier that adsorbs moisture from the air to the adsorbent and discharges the air whose moisture has been reduced to the outside and supplies the adsorbed moisture to the room again is disclosed as a “dehumidifier / humidifier” (Patent Document) 2). The humidification technology as described above can use the moisture in the air by adsorbing and desorbing the adsorbent material, so it is not necessary to continue to supply water periodically compared to the previous technology that evaporates water such as tap water. It is excellent in that there is no precipitation of a silica component accompanying evaporation of moisture.
Japanese Patent Laid-Open No. 5-168841 Japanese Patent Laid-Open No. 11-101473

  By the way, in the humidifier as described above, when moisture is adsorbed to the adsorbent from outside air or indoor air, odor components generated in the living environment are also adsorbed together with moisture. Therefore, when moisture is heated and desorbed from the adsorbent when humidifying the indoor air, the odor component is also desorbed together with the moisture, and the odorous component is accompanied by the air to be humidified and the odor drifts in the room. Occurs.

  The present invention has been made in view of the above circumstances, and its purpose is to prevent various odor components from being accompanied when moisture is desorbed from the adsorbent when the room is humidified by the moisture trapped by the adsorbent. As a result of the study, the purpose is to provide a humidifier that can further reduce leakage of odorous components trapped with moisture by the adsorbent into the room, and a humidifying method using the humidifier. It is to provide.

  In order to solve the above problems, in the present invention, by adopting an adsorbent holding mechanism that constantly replaces a specific flow path configuration and a part of the adsorbent, air exhausted from the room to the outdoors for the purpose of ventilation, Moisture is adsorbed by the adsorbent from the air or air circulating in the room, and the adsorbed moisture is desorbed in the air flowing toward the room to humidify the room air. In that case, as the adsorbent, moisture is desorbed by heating to a temperature (T1) or higher, and an adsorbent having a specific property to desorb odor components by heating to a temperature (T2) higher than the temperature (T1). In the humidification operation, the adsorbent was heated to a temperature not lower than the temperature (T1) and lower than the temperature (T2), so that substantially only moisture was selectively desorbed. Preferably, the adsorbent is heated to a temperature (T2) or higher and accumulated in the adsorbent as necessary in order to prevent a decrease in moisture adsorption performance due to the accumulated odor components and the release of saturated odor. Deodorized and removed odor components. In that case, by desorbing odor components in the flow path through which air flows outdoors, or by providing a flow path switching mechanism that switches the flow path to the outdoor side with respect to the flow path through which air flows indoors, Odor components are discharged outside.

  According to the present invention, a specific adsorbent that desorbs moisture by heating at a temperature (T1) or higher and desorbs odor components by heating at a temperature (T2) or higher than the temperature (T1) is used in a humidifying operation. The adsorbent is heated and regenerated so that the temperature is equal to or higher than the temperature (T1) and lower than the temperature (T2), and only moisture adsorbed on the adsorbent is selectively desorbed. Can comfortably humidify with no moisture. Moreover, in the aspect which performs the removal operation of the adsorbed odor component, the adsorbent is heated and regenerated so that the temperature (T2) or higher, and the odor component adsorbed on the adsorbent is desorbed and discharged outdoors. Leakage of odorous components into the room can be further reduced, and the room can always be humidified more comfortably.

  Embodiments of the present invention will be described with reference to the drawings. The present invention relates to a humidifier and a humidifier for dehumidifying the air in various rooms such as a living room, a room or a work room that needs to be humidified in a factory by desorbing moisture collected by an adsorbent. It is about the method. In the present invention, “indoor” refers to the partitioned space area as described above, and “outdoor” refers to an area around the partitioned space area. For example, when one working room in the factory building to be humidified is a room, the factory building part excluding the working room is treated as the outdoors.

  The present invention includes an aspect in which indoor moisture is utilized and an aspect in which outdoor moisture is utilized, depending on the moisture capturing method utilized for humidification. The four modes can be distinguished by the difference between the four methods: a method of supplying and exhausting air, a method of performing only exhaust air, a method of performing only air supply, and a method of not performing ventilation. And about these 4 aspects, according to the discharge | emission method of the odor component in a humidification apparatus, two aspects can be mentioned, respectively.

  FIGS. 1-8 is a top view which shows the fundamental structural example of the humidification apparatus which concerns on the 1st-4th aspect of this invention, respectively. FIG. 1 and FIG. 2 are views showing a humidifier according to a first aspect of a system that has a ventilation function for supplying and exhausting air and that collects moisture in the room. Of these, FIG. FIG. 2 is a view showing a humidifying device having a structure for discharging odorous components outdoors by a flow path switching mechanism.

  3 and 4 are views showing a humidifying device according to a second aspect of a system having a ventilation function for exhausting only and collecting moisture in the room, of which FIG. FIG. 4 is a diagram showing a humidifier having a structure for discharging odor components to the outdoors by a flow path switching mechanism.

  Further, FIGS. 5 and 6 are views showing a humidifying device according to a third aspect of a system that has a ventilation function for supplying only air and collects outdoor moisture, of which FIG. FIG. 6 is a view showing a humidifier having a structure for discharging odor components directly to a road, and FIG. 6 is a view showing a humidifier having a structure for discharging odor components outdoors by a flow path switching mechanism.

  7 and 8 are views showing a humidifier according to the fourth aspect of the method of collecting outdoor moisture without a ventilation function, of which FIG. 7 directly discharges odor components into the exhaust passage. FIG. 8 is a diagram showing a humidifier having a structure for discharging odor components outdoors by a flow path switching mechanism. In addition, FIG. 9 is a graph which shows the desorption characteristic of the water | moisture content and odor component in an example of the adsorbent applied to this invention.

  First, the humidifying device of the present invention will be described. As shown in FIG. 1, the humidifier according to the first aspect of the present invention is a humidifier that captures moisture and odor components with the adsorbent (4) and humidifies the room (7) with the trapped moisture. An air supply path (1) for supplying outdoor (6) air to the indoor (7), an exhaust path (2) for discharging indoor (7) air to the outdoor (6), and an air supply path (1) And an adsorbent holding mechanism (3) for positioning a part of the adsorbent (4) in the exhaust path (2) and replacing them, and an upstream side of the adsorbent holding mechanism (3) of the air supply path (1) Heating means (51) arranged in

  The air supply path (1) and the exhaust path (2) are so-called supply and exhaust ducts, and at least the portions where the adsorbent holding mechanism (3) is arranged are adjacent to each other in parallel and in parallel. Arranged. The cross-sectional shape orthogonal to the longitudinal direction of the air supply passage (1) and the exhaust passage (2) is usually formed in a square shape, and these cross-sectional areas are for maintaining the room (7) at a predetermined humidity. It is set taking into account the amount of humidification. Although not shown, normally, a fan for blowing air is installed in the air supply passage (1) and the exhaust passage (2), and at each inlet side of the air supply passage (1) and the exhaust passage (2). Air filter is installed.

  The adsorbent holding mechanism (3) has a structure capable of holding a necessary amount of adsorbent (4), and a part of the adsorbent (4) is positioned in the air supply path (1), At the same time, other parts of the adsorbent (4) are positioned in the exhaust passage (2), and the adsorbent (4) of the amount can be replaced. The mechanism can be adopted. For example, as shown in the figure, the adsorbent holding mechanism (3) is a short-axis cylindrical container that accommodates the adsorbent (4), and straddles the air supply path (1) and the exhaust path (2). It is configured as a rotor arranged so as to be rotatable. The configuration of the adsorbent holding mechanism (3) shown in the figure is the same as that of a so-called desiccant rotor employed in a desiccant air conditioning system.

  Specifically, the adsorbent holding mechanism (3), for example, allows the adsorbent to be supported on a porous structure, commonly called a honeycomb body, whose outer shape is formed in a short-axis cylindrical shape and which can be ventilated across its both end faces. And a drive shaft (31) provided along the center line of the rotor body and pivotally supported along the partition walls of the air supply passage (1) and the exhaust passage (2). The rotor main body is rotated at a low speed in one direction at a speed of 0.1 to 6 revolutions / minute by a driving means (not shown) such as an electric motor provided separately. Therefore, in the air supply path (1) and the exhaust path (2), the adsorbent is sequentially replaced, and the air flowing through the porous structure can be brought into contact with the adsorbent.

  A method of manufacturing a rotor body used in the adsorbent holding mechanism (3) is known as disclosed in JP-A-5-23584. That is, in the manufacture of the rotor body, for example, a honeycomb paper is formed by stacking and winding a flat inorganic fiber paper and an inorganic fiber paper that is made of inorganic fibers such as ceramic fibers and corrugated (corrugated). Make up the body. On the other hand, adsorbent powder is dispersed in a binder to prepare an adsorbent slurry. Next, the above honeycomb body is immersed in such an adsorbent slurry to support the adsorbent on the honeycomb body, and then the honeycomb body is fired in a firing furnace to remove organic components contained in the inorganic fiber paper. At the same time, the inorganic fiber paper is sintered. As a result, a rotor body in which the adsorbent is supported on the porous structure can be obtained.

  Further, the rotor portion of the adsorbent holding mechanism (3) is formed in a short-axis cylindrical shape, and has a container main body provided with a large number of small holes on both disk surfaces, and an adsorbent ( 4). As the adsorbent holding mechanism (3), in addition to the mechanism illustrated in the figure, the adsorbent holding mechanism (3) is slidably disposed over the air supply path (1) and the exhaust path (2), and has a large number of surfaces. The adsorbent (4) is respectively accommodated in two container main bodies of a thin plate with a sliding door structure provided with small holes, and each of the container main bodies is moved alternately at a constant timing, thereby supplying an air supply path (1 ) And the adsorbent (4) in the exhaust passage (2) or a boundary portion between the air supply passage (1) and the exhaust passage (2). The adsorbent (4) is accommodated in a thin plate-like container main body of a revolving door structure supported by a rotating shaft and provided with a large number of small holes on the surface, and the container main body is 180 degrees at a fixed timing. By rotating, the adsorbent (4) in the air supply path (1) and the adsorbent (4) in the exhaust path (2) Such as made the mechanism as changing, and the like. The amount of the adsorbent (4) in the adsorbent holding mechanism (3) is determined according to the type of the adsorbent and the amount of air to be humidified.

  A heating means (51) is disposed upstream of the adsorbent holding mechanism (3) in the air supply path (1) (outside air intake side). When heating means (51) desorbs moisture adsorbed on adsorbent (4), in other words, when regenerating adsorbent (4), it mainly heats the air in air supply path (1). Provided. As the heating means (51), in addition to a heating element such as an electric heater, a high-temperature heat source of a heat pump can be used. A plurality of devices constituting the heating means (51) may be provided.

  As is well known, a heat pump includes a compressor that compresses a refrigerant that is a gas, a condenser as a high-temperature heat source that heats the surrounding air (object to be heated) by cooling and condensing the compressed refrigerant, And an evaporator as a low-temperature heat source that cools the surrounding air (an object to be cooled) by evaporating the generated refrigerant. When using a heat pump, a condenser is arrange | positioned as a heating means (51) in an air supply path (1). The heating means (51) is arranged in the vicinity of the adsorbent holding mechanism (3) so that not only heating of air but also radiant heat can be used for heating of the adsorbent (4) to be regenerated. preferable.

  Furthermore, in a preferred aspect of the present invention, the cooling means (52) is arranged upstream of the adsorbent holding mechanism (3) of the exhaust passage (2) (inside of the room air intake). The cooling means (52) is provided to increase the relative humidity of the air containing moisture to be adsorbed and to increase the moisture adsorption amount of the adsorbent (4). As the cooling means (52), the above-described heat pump evaporator (low-temperature heat source) that cools the surrounding air (an object to be cooled) by evaporation of the refrigerant can be used. The air containing moisture to be adsorbed is cooled in advance by the cooling means (52) and the relative humidity is increased to, for example, about 90% or more, so that the adsorbing power of the adsorbent (4) can be maximized, It is possible to humidify more efficiently by increasing the amount of moisture desorbed in the exhaust passage (2). When the heat pump includes a plurality of evaporators and condensers, some of the evaporators and condensers of the heat pump may be used as the heating means (51) and the cooling means (52).

  In the humidifier of the present invention, in order to selectively desorb moisture and odor components, as the adsorbent (4) of the adsorbent retention mechanism (3), the moisture is desorbed by heating to a temperature (T1) or higher. An adsorbent that desorbs odor components by heating to a temperature (T2) higher than the temperature (T1) is used. The range of the temperature (T1) which is the desorption temperature of moisture is usually 40 to 100 ° C., preferably 45 to 80 ° C., more preferably 50 to 60 ° C., and the range of the temperature (T2) which is the desorption temperature of odor components. Is usually 100 to 300 ° C, preferably 100 to 200 ° C.

  In addition, as an odor component in this invention, the substance mainly described below is mentioned. That is, odorous substances in the home are described in detail in “Zeolite Science and Engineering” (published by Kodansha, Editor; Yoshio Ono and Kenaki Yajima, p. 221). Ammonia, acetic acid, acetaldehyde, hydrogen sulfide, sulfide Methyl, methylamine, trimethylamine, methyl mercaptan, isovaleric acid and the like are the main components. VOCs (volatile organic compounds) such as formaldehyde, toluene, and xylene are known as substances that are diffused indoors from building materials and fittings. It is also known that representative substances of tobacco odor include ammonia, acetic acid and acetaldehyde. In elderly welfare facilities and medical welfare facilities, removal of a living odor caused by ammonia or the like has become a problem.

  On the other hand, there is a movement to improve the passenger compartment air quality as a moving body, and the indoor concentration guideline values are set for the following 13 substances to reduce the passenger compartment. The 13 substances are as follows. Formaldehyde, toluene, xylene, paradichlorobenzene, ethylbenzene, styrene, chloropyrifos, dibutyl phthalate, tetradecane, diethylhexyl phthalate, diazinon, acetaldehyde, fenocarb. These are indicated in the guidelines of the “Study Committee on the Sick House (Indoor Air Pollution) Problem” by the Ministry of Health, Labor and Welfare.

  The adsorbent (4) has the following desorption characteristics with respect to the odor component and moisture mainly composed of ammonia. That is, the desorption characteristic of the adsorbent (4) is the ratio of the moisture desorption amount when heated from 25 ° C. to 100 ° C. with respect to the water vapor adsorption amount when water vapor is adsorbed in a dry state at 25 ° C. (water vapor desorption). The ratio of the amount of ammonia desorbed when heated from 25 ° C. to 100 ° C. relative to the amount of ammonia adsorbed when ammonia was adsorbed in a dry state at 25 ° C. ) Is 60% or less. Regarding the above desorption characteristics, the water vapor desorption ratio is preferably 70% or more and the ammonia desorption ratio is preferably 50% or less, and the water vapor desorption ratio is 80% or more and the ammonia desorption ratio is 40% or less. preferable.

  The analysis method for confirming the above characteristics is as follows. First, the adsorbent (4) is placed in a glass tube, dried at 150 ° C. for 5 hours under vacuum, and then only steam (or ammonia) vapor is introduced into the glass tube while maintaining the room temperature for 2 hours. Leave it as it is, and fully adsorb water vapor (or ammonia). And a thermogravimetry apparatus is used and it measures about a weight change when adsorbent (4) is heated sequentially.

  In the measurement of the adsorbent weight, the adsorbent (4) adsorbed with water vapor (or ammonia) is set in a thermogravimetric measuring device, and first, the adsorbent weight (W1) at room temperature is measured. Next, the adsorbent weight (W2) when heated to 10 ° C./min in a He flow of 50 ml / min and heated to 100 ° C. is measured, and further the adsorbent weight (W3 when heated to 300 ° C.). ). Since almost all vapor components are desorbed when heated to 300 ° C, the total adsorption amount is W1-W3, and the desorption amount of water vapor (or ammonia) adsorbed component when heated to 100 ° C is W1-W2 (100 ° C. desorption amount). Therefore, the desorption ratio (water vapor desorption ratio or ammonia desorption ratio) of the adsorbent (4) at 100 ° C. can be expressed by the following formula.

  The adsorbent (4) is not particularly limited as long as it has the above-mentioned adsorption characteristics, and various adsorbents can be used. However, normal Y-type zeolite needs to be heated to a relatively high temperature when dehydrating and regenerating moisture. For example, it is sufficient to desorb at a temperature of 100 ° C. or lower, preferably 80 ° C. or lower, more preferably 60 ° C. or lower. I can not. Further, normal silica can desorb moisture at a relatively low temperature, but is not suitable because odor components adsorbed with moisture are also desorbed together. In the present invention, as described above, the performance is such that only moisture is desorbed during regeneration at a relatively low temperature called temperature (T1), and odor components can be desorbed during regeneration at a high temperature called temperature (T2). Although required, as the adsorbent (4) having such performance, AlPO-based zeolite is suitable.

  The AlPO-based zeolite is a zeolite containing at least Al and P as elements other than oxygen forming the skeleton. Also, some of Al and P may be silicon, lithium, magnesium, titanium, zirconium, vanadium, chromium, manganese, iron, cobalt, nickel, palladium, copper, zinc, gallium, germanium, arsenic, tin, calcium, boron, etc. It may be substituted with a heteroatom. Such heteroatoms are preferably silicon, magnesium, titanium, iron, cobalt, nickel, copper, zinc, gallium, and boron, and more preferably silicon and iron.

In the above-described zeolite, the framework density is usually, 10.0T / 1000Å ³ or more, in the range of 20.0T / 1000Å ³ or less, preferably, 11T / 1000 Å ³ or more, 19T / 1000 Å ³ or less in the range , more preferably, 12T / 1000 Å ³ or more, in the range of 18T / 1000 Å ³ or less. The framework density means the number of elements constituting a skeleton other than oxygen per 1000 ³ of the zeolite, and this value is determined by the structure of the zeolite. The relationship between framework density and zeolite structure is shown in “ATLAS OF ZEOLITE FRAMEWARK TYPES Fifth Revised Edition 2001 ELSEVIER”.

  The structure of the zeolite as described above is represented by a code defined by IZA (International Zeolite Association). AEI, AEL, AEN, AET, AFI, AFN, AFO, AFR, AFS, AFT, AFX, Afy, AHT, ANA, APC, APD, AST, ATN, ATO, ATS, ATT, ATV, AWO, AWW, CHA, DFO, ERI, FAU, GIS, LEV, LTA, RHO, SAO, SAS, SAT, SAV, SBE, SOD, THO, VFI, ZON, etc., AEI, AET, AFI, AFN, AFR, AFS, AFT, AFX, AFY, AST, ATS, ATT, AWW, CHA, DFO, ERI, FAU, GIS, LEV, LTA, GHO, SOD, VFI and ZON are preferred, and AFI and CHA are more preferred.

  Moreover, said zeolite may contain what has a cation seed | species which can be exchanged with another cation. Examples of cations in this case include protons, alkali elements such as Li, Na, and K, alkaline earth elements such as Ca and Mg, rare earth elements such as La and Ce, and transition metal elements such as Fe, Co, and Ni. It is done. Of these, protons, alkali elements, and transition metal elements are preferable.

  The humidifier of the present invention uses the adsorbent (4) as described above, and in a routine humidifying operation, adsorbs moisture to the adsorbent (4) in the exhaust passage (2), and supplies the air supply passage ( In 1), the adsorbent (4) is heated by the heating means (51) to a temperature not lower than the temperature (T1) and lower than the temperature (T2) to desorb moisture substantially free of odor, so that the indoor (7 ) Is humidified. The humidification operation and the odor component removal operation described later are controlled by a control device (not shown) in which an operation program for driving devices such as the heating means (51) and the cooling means (52) is written in advance.

  That is, in the humidifying operation of the room (7) by the humidifying device of the present invention shown in FIG. 1, the adsorbent holding mechanism (3) is rotated at a speed of 0.01 to 6 revolutions / minute as described above, The heating means (51) and the cooling means (52) are operated. In the exhaust path (2), the air discharged to the outdoors (6) is cooled by the cooling means (52), the relative humidity is increased to, for example, 90% or more, and the adsorbent (4) of the adsorbent holding mechanism (3). To adsorb moisture in the air. On the other hand, in the air supply path (1), the air supplied to the room (7) is heated by the heating means (51) so that the adsorbent (4) is equal to or higher than the temperature (T1) and lower than the temperature (T2). Heat. The control condition of the heating means (51) can be set from the temperature of the adsorbent (4) that is experimentally determined in advance. And in the air supply path (1), the air supplied to the room (7) is humidified by selectively desorbing moisture from the adsorbent (4) by heating.

  As described above, the humidifying device of the present invention shown in FIG. 1 uses the specific adsorbent (4) described above, and adsorbs so as to be equal to or higher than the temperature (T1) and lower than the temperature (T2) in the humidifying operation. The material (4) is heated and regenerated in the air supply path (1), and only moisture adsorbed on the adsorbent (4) is selectively desorbed, so that the air supplied to the room (7) has no odor. Comfortable humidification with moisture.

  Moreover, in the humidification apparatus of said aspect, the fall of the water | moisture-content adsorption | suction performance of adsorbent (4) by the accumulated odor component is prevented, and the adsorption amount of an odor component becomes a saturated state, and adsorbent (4) In order to prevent the problem of so-called odor return that is temporarily released in large quantities, the odor component accumulated in the adsorbent (4) may be removed as necessary. For example, as shown in FIG. 1, the humidifier includes a second heating means (9) disposed upstream of the adsorbent holding mechanism (3) of the exhaust passage (2) (inside of the room air intake). In the operation of removing the odor component accumulated in the adsorbent, the adsorbent (4) is heated to the temperature (T2) or higher by the second heating means (9) in the exhaust passage (2) to cause the odor component. By desorbing the odor component, the odor component is discharged.

  Said 2nd heating means (9) is provided in order to mainly heat the air of an exhaust path (2), when desorbing the odor component adsorbed to the adsorbent (4). As the second heating means (9), since the adsorbent (4) is heated to a temperature (T2) higher than the heating temperature (T1) by the heating means (51), a heating element such as an electric heater is usually used. used. Such second heating means (9) is arranged in the vicinity of the adsorbent holding mechanism (3) so that not only heating of air but also radiant heat can be used for heating of the adsorbent (4) to be regenerated. It is preferable.

  In the humidifying device shown in FIG. 1, when it is determined that a large amount of odorous components are accumulated in the adsorbent (4) from the operation time required for humidification (when the odorous components are close to saturation). Switch to odor component removal operation. In the removal operation, the supply of air through the supply passage (1) is stopped, the operation of the cooling means (52) is stopped in the exhaust passage (2), and the second heating means (9) is operated. In the exhaust path (2), the air discharged to the outdoors (6) is heated by the second heating means (9) so that the adsorbent (4) becomes equal to or higher than the temperature (T2). The control condition of the second heating means (9) can be set from the temperature of the adsorbent (4) that is experimentally determined in advance. In the exhaust passage (2), the odor component is desorbed from the adsorbent (4) by heating, and the odor component is discharged to the outdoors (6) along with the discharged air.

  As described above, the humidifying device of the present invention shown in FIG. 1 uses the specific adsorbent (4) described above, and in the operation of removing the adsorbed odorous component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the exhaust passage (2), and the odor component adsorbed on the adsorbent (4) is desorbed and discharged from the exhaust passage (2) to the outdoors (6). 4) The moisture adsorption performance is prevented from deteriorating and there is no odor return, and leakage of odorous components into the room (7) can be further reduced. As a result, the room (7) can always be comfortably humidified. I can do it.

  Moreover, the humidifier of said aspect may be equipped with a structure as shown in FIG. 2, for example so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed. The humidifier shown in FIG. 2 includes a flow path switching mechanism (8) that is disposed on the downstream side of the adsorbent holding mechanism (3) of the air supply path (1) and switches the flow path to the outdoor (6) side. And in removal operation of the odor component accumulate | stored in the adsorbent (4), while switching the flow of an air supply path (1) to the outdoor (6) side by a flow-path switching mechanism (8), an air supply path (1) The odorous component is discharged by heating the adsorbent (4) to a temperature equal to or higher than the temperature (T2) by the heating means to desorb the odorous component.

  That is, the humidifier shown in FIG. 2 includes an air supply path (1), an exhaust path (2), an adsorbent holding mechanism (3), a heating means (51), and a flow path switching mechanism (8). The structure of the air supply path (1), the exhaust path (2), the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) is the same as the apparatus shown in FIG. In the humidifier shown in FIG. 2, the heating means (51) used for the desorption of moisture is also used for the desorption of the odor component. Therefore, the deodorization of the odor component is performed in the air supply channel (1) and the deodorized odor is obtained. In order to discharge the components into the room (7), the flow path switching mechanism (8) is disposed on the downstream side of the adsorbent holding mechanism (3) in the air supply path (1). As such a flow path switching mechanism (8), various mechanisms can be adopted as long as it is a mechanism that can change the flow of air supplied to the room (7). There is a mechanism in which a part of the door is configured as a door and the door is rotated 90 degrees by the drive shaft, thereby closing the outlet side of the flow path and releasing the middle of the flow path to the outdoor (6) side.

  Further, in the humidifying device shown in FIG. 2, preferably, in order to enhance moisture adsorption by the adsorbent (4), the adsorbent holding mechanism (3) of the exhaust passage (2) is more similar to the device shown in FIG. 1. The cooling means (52) is disposed upstream (inside the room air intake port). The structure of the cooling means (52) is the same as that in the apparatus shown in FIG. Furthermore, preferably, in order to eliminate the overload of the heating means (51) in the desorption operation of the odor component and to heat the adsorbent (4) more efficiently, the adsorbent holding mechanism (3) of the air supply path (1) The second heating means (9) is arranged on the upstream side (outdoor air intake side). The configuration of the second heating means (9) is the same as that in the apparatus shown in FIG.

  In the humidifying device shown in FIG. 2, the room (7) can be humidified as in the device shown in FIG. In the odor component removal operation, the operation of the cooling means (52) is stopped in the exhaust passage (2), and the flow passage switching mechanism (8) is operated in the air supply passage (1) to supply the air supply passage ( Close the exit side of 1) and release the middle part to the outside (6) side. Further, the temperature or output of the heating means (51) is increased, or the temperature or output of the heating means (51) is increased and the second heating means (9) is operated. Then, in the air supply path (1), the air in the air supply path (1) is heated so that the adsorbent (4) becomes equal to or higher than the temperature (T2). By such an operation, the odor component is desorbed from the adsorbent (4), and the odor component is entrained by the exhausted air through the channel to the outdoor (6) side switched by the channel switching mechanism (8). Discharge outdoors (6).

  As described above, the humidifying device of the present invention shown in FIG. 2 uses the specific adsorbent (4) described above, and in the operation of removing the adsorbed odor component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the air supply path (1) to desorb the odor component adsorbed on the adsorbent (4) and from the air supply path (1) switched to the outdoor (6) side. Since the odor components are discharged to the outdoors (6), the moisture adsorption performance of the adsorbent (4) is prevented from being reduced and there is no odor return, resulting in further leakage of the odor components into the room (7). It can be reduced and the room (7) can always be humidified comfortably.

  Next, the humidifying device according to the second aspect of the present invention will be described. As shown in FIG. 3, the humidifier according to the second aspect is a humidifier that captures moisture and odor components with the adsorbent (4) and humidifies the room (7) with the trapped moisture. 7) an exhaust path (2) for discharging the air to the outdoors (6), an indoor air flow path (21) for taking in the air in the room (7) and returning it to the room (7), an exhaust path (2), and More than the adsorbent holding mechanism (3) for positioning a part of the adsorbent (4) in the indoor air flow path (21) and replacing them, and the adsorbent holding mechanism (3) of the indoor air flow path (21) Heating means (51) disposed on the upstream side.

  The exhaust passage (2) is configured, for example, by bending its outlet side so that it can be easily installed, but is functionally the same as in the above-described embodiment. The configurations of the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) are the same as those in the above-described embodiment. In the humidifier shown in FIG. 3, in order to collect moisture from the air discharged from the room (7) and humidify the room (7) with the collected moisture, the indoor air flow path is adjacent to the exhaust path (2). (21) is provided. The indoor air flow path (21) is a duct having the same structure as the above-described air supply path (1) and exhaust path (2), and has a function of circulating the air in the room (7).

  Moreover, in the preferable aspect of this invention, in order to raise the adsorption | suction of the water | moisture content by an adsorbent (4) similarly to the above-mentioned aspect, it is upstream (room air) rather than the adsorbent holding mechanism (3) of an exhaust path (2). The cooling means (52) is disposed on the intake side of the first. The structure of the cooling means (52) is the same as that in the above-described embodiment.

  Also in the humidifying device of the present invention shown in FIG. 3, in order to selectively desorb moisture and odor components, an adsorbent similar to that in the above-described embodiment is used as the adsorbent (4) of the adsorbent holding mechanism (3). used. In the routine humidification operation, moisture is adsorbed by the adsorbent (4) in the exhaust passage (2), and the temperature (T1) is exceeded by the heating means (51) in the indoor air flow path (21). The adsorbent (4) is heated to a temperature lower than T2) to desorb moisture substantially free of odor, thereby humidifying the room (7). The humidification operation and the odor component removal operation described later are controlled by a control device (not shown) in the same manner as described above.

  In the humidification operation of the room (7) by the humidifier of the present invention shown in FIG. 3, the adsorbent holding mechanism (3) is rotated as described above, and at the same time, the heating means (51) and the cooling means (52) are operated. . In the exhaust path (2), the air discharged to the outdoors (6) is cooled by the cooling means (52) to increase its relative humidity, and the moisture in the air is absorbed by the adsorbent (4) of the adsorbent holding mechanism (3). To adsorb. On the other hand, in the indoor air flow path (21), the air supplied to the room (7) is heated by the heating means (51) so that the adsorbent (4) is equal to or higher than the temperature (T1) and lower than the temperature (T2). Heat by. And in the indoor air flow path (21), the air supplied to the room (7) is humidified by selectively desorbing moisture from the adsorbent (4) by heating.

  As described above, the humidifying device of the present invention shown in FIG. 3 uses the specific adsorbent (4) described above, and adsorbs so as to be equal to or higher than the temperature (T1) and lower than the temperature (T2) in the humidifying operation. The material (4) is heated and regenerated in the indoor air flow path (21), and only the water adsorbed on the adsorbent (4) is selectively desorbed. Can comfortably humidify with no moisture.

  Moreover, in the humidification apparatus of this invention shown in FIG. 3, similarly to the aspect shown in FIG. 1, you may be comprised so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed. For example, as shown in FIG. 3, the humidifier includes a second heating means (9) arranged upstream of the adsorbent holding mechanism (3) of the exhaust passage (2), and the adsorbent In the operation of removing the accumulated odor component, the odor component is desorbed by heating the adsorbent (4) to the temperature (T2) or higher by the second heating means (9) in the exhaust passage (2). It is made to discharge.

  Said 2nd heating means (9) is provided in order to mainly heat the air of an exhaust path (2), when desorbing the odor component adsorbed to the adsorbent (4). The second heating means (9) usually has the same configuration as that in the embodiment shown in FIG. 1, and the adsorbent holding mechanism so that the radiant heat can be used for heating the adsorbent (4). It is preferable to arrange in the vicinity of (3).

  In the humidifier shown in FIG. 3, in the odor component removal operation, the supply of air (circulation of room air) by the indoor air flow path (21) is stopped, and the cooling means (52) is activated in the exhaust path (2). And the second heating means (9) is activated. The control condition of the second heating means (9) can be set from the temperature of the adsorbent (4) obtained experimentally in advance, as in the above-described embodiment. In the exhaust path (2), the air discharged to the outdoors (6) is heated by the second heating means (9) so that the adsorbent (4) becomes equal to or higher than the temperature (T2). Then, the odor component is desorbed from the adsorbent (4) by heating, and the odor component is discharged to the outdoors (6) along with the air discharged from the exhaust passage (2).

  As described above, the humidifying device of the present invention shown in FIG. 3 uses the specific adsorbent (4) described above, and in the operation for removing the adsorbed odorous component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the exhaust passage (2), and the odor component adsorbed on the adsorbent (4) is desorbed and discharged from the exhaust passage (2) to the outdoors (6). 4) The moisture adsorption performance is prevented from deteriorating and there is no odor return, and leakage of odorous components into the room (7) can be further reduced. As a result, the room (7) can always be comfortably humidified. I can do it.

  Moreover, the humidifier of said aspect may be equipped with the structure as shown in FIG. 4, for example so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed. The humidifier shown in FIG. 4 includes a flow path switching mechanism (8) that is arranged on the downstream side of the adsorbent holding mechanism (3) of the indoor air flow path (21) and switches the flow path to the outdoor (6) side. In the operation of removing the odor component accumulated in the adsorbent (4), the flow of the indoor air flow path (21) is switched to the outdoor (6) side by the flow path switching mechanism (8), and the indoor air flow path is switched. In (21), the adsorbent (4) is heated to a temperature equal to or higher than the temperature (T2) by the heating means to desorb the odor component, thereby discharging the odor component.

  That is, the humidifier shown in FIG. 4 includes an air supply path (1), an indoor air flow path (21), an adsorbent holding mechanism (3), a heating means (51), and a flow path switching mechanism (8). . The structure of the air supply path (1), the indoor air flow path (21), the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) is the same as the apparatus shown in FIG. In the humidifying apparatus shown in FIG. 4, since the heating means (51) is also used for desorption of odor components, the odor components are desorbed in the indoor air flow path (21), and the desorbed odor components are removed outdoors (6 ) Is disposed in the indoor air flow path (21). The flow path switching mechanism (8) closes the outlet side of the indoor air flow path (21) and connects the downstream side of the indoor air flow path (21) to the exhaust path (2), for example, by a door structure on the side wall. Configured. The structure of the flow path switching mechanism (8) itself is the same as that in the embodiment shown in FIG.

  Further, in the humidifying device shown in FIG. 4, preferably, in the same manner as the device shown in FIG. The cooling means (52) is disposed upstream (inside the room air intake port). The structure of the cooling means (52) is the same as that in the apparatus shown in FIG. Furthermore, in order to eliminate the overload of the heating means (51) in the desorption operation of the odor component and to heat the adsorbent (4) more efficiently than the adsorbent holding mechanism (3) of the indoor air flow path (21). The second heating means (9) is arranged on the upstream side (outdoor air intake side). The configuration of the second heating means (9) is the same as that in the apparatus shown in FIG.

  In the humidifying device of the present invention shown in FIG. 4, the room (7) can be humidified similarly to the device shown in FIG. In the odor component removal operation, the operation of the cooling means (52) is stopped in the exhaust passage (2), and the flow path switching mechanism (8) is operated in the indoor air flow path (21) to The outlet side of the flow path is closed, and the downstream side of the indoor air flow path (21) is released to the outdoor (6) side, that is, the downstream side of the exhaust path (2). Further, the temperature or output of the heating means (51) is increased, or the temperature or output of the heating means (51) is increased and the second heating means (9) is operated. And in an indoor air flow path (21), the air of an indoor air flow path (21) is heated so that adsorption material (4) may become temperature (T2) or more. By such an operation, the odor component is desorbed from the adsorbent (4), and the flow path to the outdoor (6) side switched by the flow path switching mechanism (8), that is, the downstream side of the exhaust path (2) is reached. The odor component is discharged to the outdoors (6) through the flow path along with the discharged air.

  As described above, the humidifying apparatus of the present invention shown in FIG. 4 uses the specific adsorbent (4) described above, and the adsorption is performed so that the temperature (T2) or higher in the operation for removing the adsorbed odor component. The material (4) is heated and regenerated in the indoor air flow path (21) to desorb the odor component adsorbed on the adsorbent (4) and switch to the outdoor (6) side (exhaust path (2) side). Since the odor component is discharged from the indoor air flow path (21) thus formed to the outdoors (6), the moisture adsorption performance of the adsorbent (4) is prevented from being lowered, and there is no odor return. As a result, the indoor ( Leakage of odor components to 7) can be further reduced, and the room (7) can always be comfortably humidified.

  Next, a humidifier according to a third aspect of the present invention will be described. As shown in FIG. 5, the humidifier according to the third aspect is a humidifier that captures moisture and odor components with the adsorbent (4) and humidifies the room (7) with the trapped moisture. 6) an air supply path (1) for supplying air into the room (7), an outside air flow path (11) for taking in air from the outdoors (6) and discharging it to the outdoors (6), and an air supply path (1) ) And the outside air flow path (11) respectively, and a part of the adsorbent (4) is positioned and replaced with the adsorbent holding mechanism (3) and the adsorbent holding mechanism (3) of the air supply path (1). Heating means (51) disposed on the upstream side.

  Each structure of an air supply path (1), an adsorbent holding mechanism (3), an adsorbent (4), and a heating means (51) is the same as the structure in the above-mentioned aspect. In the humidifier shown in FIG. 5, moisture is collected from the outdoor (6) air, and the room (7) is humidified by the collected moisture, so that the outside air channel (11) is adjacent to the air supply channel (1). Is provided. The outside air flow path (11) is structurally a duct similar to the above-described air supply path (1) and exhaust path (2), and has a function of circulating outdoor (6) air into the apparatus.

  Moreover, in the preferable aspect of this invention, in order to raise the adsorption | suction of the water | moisture content by an adsorbent (4) similarly to the above-mentioned aspect, it is upstream (outdoors) from the adsorbent holding mechanism (3) of an external air flow path (11). Cooling means (52) is arranged on the air intake side. The structure of the cooling means (52) is the same as that in the above-described embodiment.

  Also in the humidifying device of the present invention shown in FIG. 5, in order to selectively desorb moisture and odor components, the same adsorbent as in the above-described embodiment is used as the adsorbent (4) of the adsorbent holding mechanism (3). used. In the daily humidification operation, in the daily humidification operation, moisture is adsorbed to the adsorbent (4) in the outside air flow path (11), and the temperature is increased by the heating means (51) in the air supply path (1). The adsorbent (4) is heated to a temperature equal to or higher than (T1) and lower than the temperature (T2) to dehumidify moisture substantially free of odor, thereby humidifying the room (7). . The humidification operation and the odor component removal operation described later are controlled by a control device (not shown) in the same manner as described above.

  In the humidification operation of the room (7) by the humidifier of the present invention shown in FIG. 5, the adsorbent holding mechanism (3) is rotated as described above, and at the same time, the heating means (51) and the cooling means (52) are operated. . In the outside air flow path (11), the outdoor (6) air taken in is cooled by the cooling means (52) to increase the relative humidity, and the adsorbent (4) of the adsorbent holding mechanism (3) Adsorbs moisture. On the other hand, in the air supply path (1), the air supplied to the room (7) is heated by the heating means (51) so that the adsorbent (4) is equal to or higher than the temperature (T1) and lower than the temperature (T2). Heat. And in the air supply path (1), the air supplied to the room (7) is humidified by selectively desorbing moisture from the adsorbent (4) by heating.

  As described above, the humidifying device of the present invention shown in FIG. 5 uses the specific adsorbent (4) described above, and adsorbs so as to be equal to or higher than the temperature (T1) and lower than the temperature (T2) in the humidifying operation. The material (4) is heated and regenerated in the air supply passage (1), and only the water adsorbed on the adsorbent (4) is selectively desorbed, so that the material (4) is supplied to the room (7) through the air supply passage (1). Can be humidified by moisture without odor.

  Further, the humidifying device of the present invention shown in FIG. 5 may be configured so that the odor component accumulated in the adsorbent (4) can be removed as necessary, similarly to the embodiment shown in FIGS. Good. For example, as shown in FIG. 5, the humidifier includes a second heating means (9) arranged upstream of the adsorbent holding mechanism (3) of the outside air flow path (11), and the adsorbent. In the operation of removing the odor component accumulated in (4), the adsorbent (4) is heated to the temperature (T2) or higher by the second heating means (9) in the outside air flow path (11) to desorb the odor component. Therefore, the odor component is discharged.

  Said 2nd heating means (9) is provided in order to mainly heat the air of an external air flow path (11), when desorbing the odor component adsorbed to the adsorbent (4). The second heating means (9) usually has the same configuration as in the embodiment shown in FIGS. 1 and 3, and adsorbing so that radiant heat can be used in heating the adsorbent (4). It is preferable to arrange in the vicinity of the material holding mechanism (3).

  In the humidifying device shown in FIG. 5, in the odor component removal operation, the supply of air through the supply passage (1) is stopped, and the operation of the cooling means (52) is stopped in the outside air passage (11). The heating means (9) is activated. The control condition of the second heating means (9) can be set from the temperature of the adsorbent (4) obtained experimentally in advance, as in the above-described embodiment. In the outside air flow path (11), the outdoor (6) air flowing is heated by the second heating means (9) so that the adsorbent (4) becomes equal to or higher than the temperature (T2). Then, the odor component is desorbed from the adsorbent (4) by heating, and the odor component is discharged to the outdoors (6) along with the air discharged from the outside air flow path (11).

  As described above, the humidifying apparatus of the present invention shown in FIG. 5 uses the specific adsorbent (4) described above, and in the operation of removing the adsorbed odor component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the outside air flow path (11), and the odor component adsorbed on the adsorbent (4) is desorbed and discharged to the outside (6) through the outside air flow path (11). Decrease in moisture adsorption performance of the material (4) is prevented, and there is no odor return, etc., and leakage of odorous components into the room (7) can be further reduced. As a result, the room (7) is always comfortably humidified. I can do it.

  Moreover, the humidification apparatus of said aspect may be equipped with the structure as shown in FIG. 6, for example so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed. The humidifier shown in FIG. 6 includes a flow path switching mechanism (8) that is disposed on the downstream side of the adsorbent holding mechanism (3) of the air supply path (1) and switches the flow path to the outdoor (6) side. And in removal operation of the odor component accumulate | stored in the adsorbent (4), while switching the flow of an air supply path (1) to the outdoor (6) side by a flow-path switching mechanism (8), an air supply path (1) The odorous component is discharged by heating the adsorbent (4) to a temperature (T2) or higher by the heating means (51) to desorb the odorous component.

  That is, the humidifier shown in FIG. 6 includes an air supply path (1), an outside air flow path (11), an adsorbent holding mechanism (3), a heating means (51), and a flow path switching mechanism (8). The structure of the air supply path (1), the outside air flow path (11), the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) is the same as that of the apparatus shown in FIG. In the humidifier shown in FIG. 6, since the heating means (51) is also used for desorption of the odor component, the deodorization of the odor component is performed in the air supply path (1) and the deodorized odor component is removed outdoors (6). The flow path switching mechanism (8) is disposed in the air supply path (1). The flow path switching mechanism (8) closes the outlet side of the air supply path (1) by, for example, a side wall door structure, and opens the middle of the air supply path (1) to the outdoor (6) side, for example. Configured. The structure of the flow path switching mechanism (8) itself is the same as in the embodiment shown in FIGS.

  Further, in the humidifying device shown in FIG. 6, preferably, in the same manner as the device shown in FIG. 5, in order to increase moisture adsorption by the adsorbent (4), from the adsorbent holding mechanism (3) of the outside air flow path (11). Also, the cooling means (52) is arranged on the upstream side (outdoor air intake side). The structure of the cooling means (52) is the same as that in the apparatus shown in FIG. Furthermore, in order to eliminate the overload of the heating means (51) in the desorption operation of the odor component and to heat the adsorbent (4) more efficiently, the adsorbent holding mechanism (3) in the air supply path (1) is upstream. The second heating means (9) is arranged on the side (outdoor air intake side). The configuration of the second heating means (9) is the same as that in the apparatus shown in FIG.

  In the humidifying device of the present invention shown in FIG. 6, the room (7) can be humidified similarly to the device shown in FIG. In the odor component removal operation, the operation of the cooling means (52) is stopped, and in the air supply path (1), the flow path switching mechanism (8) is operated to close the outlet side of the air supply path, The middle of the air supply path (1) is released to the outside (6) side. Further, the temperature or output of the heating means (51) is increased, or the temperature or output of the heating means (51) is increased and the second heating means (9) is operated. Then, in the air supply path (1), the air in the air supply path (1) is heated so that the adsorbent (4) becomes equal to or higher than the temperature (T2). By such an operation, the odor component is desorbed from the adsorbent (4), and the odor component is entrained by the exhausted air through the channel to the outdoor (6) side switched by the channel switching mechanism (8). Discharge outdoors (6).

  As described above, the humidifying device of the present invention shown in FIG. 6 uses the specific adsorbent (4), and adsorbs the adsorbed odorous component so that the adsorbed odorous component is at a temperature (T2) or higher. The material (4) is heated and regenerated in the air supply path (1) to desorb the odor component adsorbed on the adsorbent (4) and from the air supply path (1) switched to the outdoor (6) side. Since the odor components are discharged to the outdoors (6), the moisture adsorption performance of the adsorbent (4) is prevented from being reduced and there is no odor return, resulting in further leakage of the odor components into the room (7). It can be reduced and the room (7) can always be humidified comfortably.

  Next, a humidifier according to a fourth aspect of the present invention will be described. As shown in FIG. 7, the humidifier according to the fourth aspect is a humidifier that captures moisture and odor components with the adsorbent (4) and humidifies the room (7) with the trapped moisture. An outdoor air flow path (11) that takes in the air of 6) and discharges it again outdoors (6), an indoor air flow path (21) that takes in the air in the room (7) and returns it to the indoor (7), and an external airflow An adsorbent holding mechanism (3) for positioning a part of the adsorbent (4) in each of the passage (11) and the indoor air flow path (21) and replacing them, and an adsorbent holding mechanism for the indoor air flow path (21) And heating means (51) disposed upstream of (3).

  The outside air flow path (11) is configured, for example, by bending its inlet side and outlet side so that it can be easily installed, but is functionally the same as in the above-described embodiment. The configurations of the indoor air flow path (21), the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) are the same as those in the above-described embodiment. In the humidifier shown in FIG. 7, moisture is collected from the outdoor (6) air, and the room (7) is humidified by the collected moisture. An indoor air flow path (21) is provided adjacent to the air flow path (11).

  Moreover, in the preferable aspect of this invention, in order to raise the adsorption | suction of the water | moisture content by an adsorbent (4) similarly to the above-mentioned aspect, it is upstream (outdoors) from the adsorbent holding mechanism (3) of an external air flow path (11). Cooling means (52) is arranged on the air intake side. The structure of the cooling means (52) is the same as that in the above-described embodiment.

  Also in the humidifier of the present invention shown in FIG. 7, in order to selectively desorb moisture and odor components, an adsorbent similar to that in the above-described embodiment is used as the adsorbent (4) of the adsorbent holding mechanism (3). used. In a daily humidification operation, moisture is adsorbed by the adsorbent (4) in the outdoor air flow path (11), and the temperature (T1) is exceeded by the heating means (51) in the indoor air flow path (21). By heating the adsorbent (4) to a temperature lower than (T2) to desorb moisture, the room (7) is humidified. The humidification operation and the odor component removal operation described later are controlled by a control device (not shown) in the same manner as described above.

  In the humidification operation of the room (7) by the humidifier of the present invention shown in FIG. 7, the adsorbent holding mechanism (3) is rotated as described above, and at the same time, the heating means (51) and the cooling means (52) are operated. . In the outside air flow path (11), the outdoor (6) air taken in is cooled by the cooling means (52) to increase the relative humidity, and the adsorbent (4) of the adsorbent holding mechanism (3) Adsorbs moisture. On the other hand, in the indoor air flow path (21), the air supplied to the room (7) is heated by the heating means (51) so that the adsorbent (4) is equal to or higher than the temperature (T1) and lower than the temperature (T2). Heat by. And in the indoor air flow path (21), the air supplied to the room (7) is humidified by selectively desorbing moisture from the adsorbent (4) by heating.

  As described above, the humidifying device of the present invention shown in FIG. 7 uses the specific adsorbent (4) described above, and adsorbs so as to be at or above the temperature (T1) and below the temperature (T2) in the humidifying operation. The material (4) is heated and regenerated in the indoor air flow path (21), and only the water adsorbed on the adsorbent (4) is selectively desorbed. Can be humidified with no moisture.

  Moreover, in the humidification apparatus of this invention shown in FIG. 7, it is comprised so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed similarly to the aspect shown in FIG.1, FIG3 and FIG.5. May be. For example, as shown in FIG. 7, the humidifier includes a second heating means (9) disposed upstream of the adsorbent holding mechanism (3) of the outside air flow path (11), and the adsorbent. In the operation of removing the odor component accumulated in (4), the adsorbent (4) is heated to the temperature (T2) or higher by the second heating means (9) in the outside air flow path (11) to desorb the odor component. Therefore, the odor component is discharged.

  Said 2nd heating means (9) is provided in order to mainly heat the air of an external air flow path (11), when desorbing the odor component adsorbed to the adsorbent (4). The second heating means (9) usually has the same configuration as that in the embodiment shown in FIGS. 1, 3 and 5, and radiant heat can be used for heating the adsorbent (4). Furthermore, it is preferable to arrange in the vicinity of the adsorbent holding mechanism (3).

  In the humidifying device shown in FIG. 7, in the odor component removal operation, the supply of air (circulation of room air) by the indoor air flow path (21) is stopped, and the cooling means (52) of the outside air flow path (11) is stopped. The operation is stopped and the second heating means (9) is activated. The control condition of the second heating means (9) can be set from the temperature of the adsorbent (4) obtained experimentally in advance, as in the above-described embodiment. In the outside air flow path (11), the outdoor (6) air flowing is heated by the second heating means (9) so that the adsorbent (4) becomes equal to or higher than the temperature (T2). Then, the odor component is desorbed from the adsorbent (4) by heating, and the odor component is discharged to the outdoors (6) along with the air discharged from the outside air flow path (11).

  As described above, the humidifying device of the present invention shown in FIG. 7 uses the specific adsorbent (4) described above, and in the operation of removing the adsorbed odor component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the outside air flow path (11), and the odor component adsorbed on the adsorbent (4) is desorbed and discharged to the outside (6) through the outside air flow path (11). Decrease in moisture adsorption performance of the material (4) is prevented, and there is no odor return, etc., and leakage of odorous components into the room (7) can be further reduced. As a result, the room (7) is always comfortably humidified. I can do it.

  Moreover, the humidifier of said aspect may be equipped with the structure as shown in FIG. 8, for example so that the odor component accumulate | stored in the adsorbent (4) can be removed as needed. The humidifier shown in FIG. 8 includes a flow path switching mechanism (8) that is disposed on the downstream side of the adsorbent holding mechanism (3) of the indoor air flow path (21) and switches the flow path to the outdoor (6) side. In the operation of removing the odor component accumulated in the adsorbent (4), the flow of the indoor air flow path (21) is switched to the outdoor (6) side by the flow path switching mechanism (8), and the indoor air flow path is switched. In (21), the adsorbent (4) is heated to the temperature (T2) or higher by the heating means (51) to desorb the odor component, thereby discharging the odor component.

  That is, the humidifier shown in FIG. 8 includes an indoor air flow path (21), an outdoor air flow path (11), an adsorbent holding mechanism (3), a heating means (51), and a flow path switching mechanism (8). . The configurations of the indoor air flow path (21), the outdoor air flow path (11), the adsorbent holding mechanism (3), the adsorbent (4), and the heating means (51) are the same as those of the apparatus shown in FIG. In the humidifier shown in FIG. 8, since the heating means (51) is also used for desorption of odor components, the deodorization of odor components is performed in the indoor air flow path (21), and the deodorized odor components are removed outdoors (6 ) Is disposed in the indoor air flow path (21). The flow path switching mechanism (8) closes the outlet side of the indoor air flow path (21) and connects the downstream side of the indoor air flow path (21) to the outdoor air flow path (11), for example, by a door structure on the side wall. Configured to do. The structure of the flow path switching mechanism (8) itself is the same as that in the embodiment shown in FIGS.

  Further, in the humidifying device shown in FIG. 8, preferably, in the same manner as the device shown in FIG. 7, in order to enhance the moisture adsorption by the adsorbent (4), the adsorbent holding mechanism (3) of the outside air flow path (11). Also, the cooling means (52) is arranged on the upstream side (outdoor air intake side). The structure of the cooling means (52) is the same as that in the apparatus shown in FIG. Furthermore, in order to eliminate the overload of the heating means (51) in the desorption operation of the odor component and to heat the adsorbent (4) more efficiently than the adsorbent holding mechanism (3) of the indoor air flow path (21). A second heating means (9) is disposed on the upstream side (the room air intake side). The configuration of the second heating means (9) is the same as that in the apparatus shown in FIG.

  In the humidifying device of the present invention shown in FIG. 8, the room (7) can be humidified similarly to the device shown in FIG. In the odor component removal operation, the operation of the cooling means (52) is stopped in the outdoor air flow path (11), and the flow path switching mechanism (8) is operated in the indoor air flow path (21). The outlet side of the air flow path is closed, and the downstream side of the indoor air flow path (21) is released to the outdoor (6) side, that is, the downstream side of the outdoor air flow path (11). Further, the temperature or output of the heating means (51) is increased, or the temperature or output of the heating means (51) is increased and the second heating means (9) is operated. And in an indoor air flow path (21), the air of an indoor air flow path (21) is heated so that adsorption material (4) may become temperature (T2) or more. By such an operation, the odor component is desorbed from the adsorbent (4), and the channel to the outdoor (6) side switched by the channel switching mechanism (8), that is, the downstream side of the outside air channel (11). The odorous component is discharged to the outside (6) by being accompanied by the discharged air through the flow path to reach.

  As described above, the humidifying device of the present invention shown in FIG. 8 uses the specific adsorbent (4) described above, and in the operation of removing the adsorbed odor component, the adsorbing is performed so that the temperature becomes equal to or higher than the temperature (T2). The material (4) is heated and regenerated in the outside air flow path (11) to desorb the odor component adsorbed on the adsorbent (4) and switched to the outdoor (6) side (outside air flow path (11) side). Since the odor component is discharged from the indoor air flow path (21) thus formed to the outdoors (6), the moisture adsorption performance of the adsorbent (4) is prevented from being lowered, and there is no odor return. As a result, the indoor ( Leakage of odor components to 7) can be further reduced, and the room (7) can always be comfortably humidified.

  In addition, the humidifier of this invention may be comprised in the air conditioner provided with the dehumidification function and the temperature control function. Further, in the humidifying device of each aspect described above, the air volume of the air supply path (1), the exhaust path (2), the outdoor air flow path (11), the indoor air flow path (21), and the adsorbent holding mechanism (3 ) Is set in consideration of the size of the room (7) to be humidified and the target humidity. Further, in the humidification operation and the odor component removal operation, the adsorbent (4) is stored. It is also possible to increase the air volume of the heated air supplied to.

  Further, the humidifying method of the present invention is a humidifying method that uses the humidifying device of each aspect described above and performs indoor (7). According to the humidifying method of the present invention, the specific adsorbent (4) is used. In the humidification operation, the adsorbent (4) is heated and regenerated so that the temperature is equal to or higher than the temperature (T1) and lower than the temperature (T2), and only moisture adsorbed on the adsorbent (4) is selectively desorbed. Therefore, the air supplied to the room (7) can be comfortably humidified by moisture without odor.

  Furthermore, the humidification method of the present invention uses a humidifier as shown in FIGS. 1 to 8 having a function of removing the odor component adsorbed on the adsorbent (4), humidifies the room, and if necessary. This is a humidification method for discharging the odor component adsorbed to the adsorbent to the outdoors. According to the humidification method of the present invention, the above-mentioned specific adsorbent is used. The adsorbent (4) can be humidified comfortably with moisture without odor, and the adsorbent (4) is heated and regenerated so that the temperature becomes equal to or higher than the temperature (T2) in the operation of removing the adsorbed odor component. Since the odor component adsorbed on the inside is desorbed and discharged to the outside (6), leakage of the odor component into the room (7) can be further reduced, and the room (7) can always be humidified more comfortably.

  The desorption characteristics of the adsorbent (4) suitable for the present invention and the conventional adsorbent were compared. As the adsorbent (4) suitable for the present invention, FAPO5 and SAPO34 of aluminophosphates were prepared, and thermogravimetric measurement was performed according to the above-described analysis method, and the respective moisture desorption ratios and ammonia desorption ratios at 100 ° C. were determined. Confirmed (Examples 1 and 2). FAPO5 is an AFI-type Fe aluminophosphate (Fe / (Fe + Al + P) molar ratio is 4.5%), and SAPO34 is a CHA-type silicoaluminophosphate (Si / (Si + Al + P) molar ratio of 8. 8%). On the other hand, A-type silica gel and Na-type Y zeolite (silica / alumina molar ratio is 5) were prepared as conventional adsorbents. And the ammonia desorption ratio was confirmed (Comparative Examples 1 and 2). Each result is shown in the following table.

  Incidentally, as an example of a suitable adsorbent (4), the desorption characteristics of FAPO5, which is an AFI-type zeolite containing Fe as a hetero atom, are shown in FIG. Such desorption characteristics are results obtained by thermogravimetric analysis of adsorbed water and ammonia, which is an odor component, in a 50 ml / min He stream under a temperature rising condition of 10 ° C./min. According to the graph shown in FIG. 9, water is almost desorbed at 100 ° C. or lower, for example, 80 ° C., but ammonia is hardly desorbed. The adsorbent (4) is Although it can be easily detached, the odor component is difficult to desorb.

  Furthermore, regarding the desorption characteristics of SAPO 34 used in Example 2, the desorption ratio at 100 ° C. was measured in the same manner as in Example 2 for xylene, acetaldehyde, and acetic acid instead of ammonia as the odor component (Example 3). . As a result, the water vapor desorption ratio was 86% (see Example 2), while the xylene desorption ratio was 38%, the acetaldehyde desorption ratio was 53%, and the acetic acid desorption ratio was 54%. From this, it can be seen that SAPO 34 is also less likely to desorb odor components other than ammonia compared to water vapor.

It is a top view which shows one structural example of the humidification apparatus which concerns on the 1st aspect of this invention, and is a humidification apparatus of the type | system | group which is equipped with the ventilation function which supplies and exhausts air, and collect | recovers indoor moisture, Comprising: It is a figure of the humidification apparatus of the structure which discharges | emits an odor component directly. It is a top view which shows the other structural example of the humidification apparatus which concerns on the 1st aspect of this invention, and is a humidification apparatus of the type | system | group which is equipped with the ventilation function which supplies and exhausts air, and collect | recovers indoor moisture, It is a figure of the humidification apparatus of the structure which discharges | emits an odor component outdoors by a switching mechanism. It is a top view which shows one structural example of the humidification apparatus which concerns on the 2nd aspect of this invention, is a humidification apparatus of the type | system | group which is equipped with the ventilation function which performs only exhaust_gas | exhaustion, and collect | recovers indoor water | moisture content, Comprising: It is a figure of the humidification apparatus of the structure which discharges | emits directly. It is a top view which shows the other structural example of the humidification apparatus which concerns on the 2nd aspect of this invention, and is a humidification apparatus of the type | system | group which is equipped with the ventilation function which performs only exhaust_gas | exhaustion, and collect | recovers indoor moisture, Comprising: It is a figure of the humidification apparatus of the structure which discharge | emits an odor component outdoors by. It is a top view which shows one structural example of the humidification apparatus which concerns on the 3rd aspect of this invention, and is a humidification apparatus of the type | system | group provided with the ventilation function which collects only air supply, and collect | recovers outdoor water | moisture content. It is a figure of the humidification apparatus of the structure which discharges | emits a component directly. It is a top view which shows the other structural example of the humidification apparatus which concerns on the 3rd aspect of this invention, is a humidification apparatus of the system which has the ventilation function which collects only air supply, and collect | recovers outdoor moisture, Comprising: It is a figure of the humidification apparatus of a structure which discharges | emits an odor component outdoors by a mechanism. It is a top view which shows one structural example of the humidification apparatus which concerns on the 4th aspect of this invention, and is a humidification apparatus of the system which does not have a ventilation function and collect | recovers outdoor water | moisture content, Comprising: An odor component is discharged | emitted directly to an exhaust path It is a figure of the humidification apparatus of structure. It is a top view which shows the other structural example of the humidification apparatus which concerns on the 4th aspect of this invention, and is a humidification apparatus of the type | system | group which does not have a ventilation function and collect | recovers outdoor water | moisture content, Comprising: It is a figure of the humidification apparatus of the structure which discharges | emits a component. It is a graph which shows the desorption characteristic of the water | moisture content and odor component in an example of the adsorbent applied to this invention.

Explanation of symbols

1: Air supply path 11: Outside air flow path 2: Exhaust path 21: Indoor air flow path 3: Adsorbent holding mechanism 4: Adsorbent 51: Heating means 52: Cooling means 6: Outdoor 7: Indoor 8: Flow path switching mechanism 9: Second heating means

Claims (16)

  A humidifier that traps moisture and odor components with an adsorbent and humidifies the room with the trapped moisture, an air supply path for supplying outdoor air to the room, and an exhaust path for discharging indoor air to the outdoors An adsorbent holding mechanism that positions and replaces a part of the adsorbent in each of the air supply path and the exhaust path, and a heating means that is disposed upstream of the adsorbent holding mechanism in the air supply path. And the adsorbent desorbs moisture by heating to a temperature (T1) or higher, and desorbs odor components by heating to a temperature (T2) higher than the temperature (T1). Then, moisture is adsorbed by the adsorbent in the exhaust passage, and the adsorbent is heated to a temperature not lower than the temperature (T1) and lower than the temperature (T2) by the heating means in the air supply passage to substantially accompany odor. No moisture removal By humidifying apparatus characterized by being made so as to perform a humidifying for the room.   A second heating means disposed upstream of the adsorbent holding mechanism in the exhaust passage, and if necessary, the adsorbent is heated to a temperature (T2) or higher by the second heating means in the exhaust passage; The humidifier according to claim 1, wherein the odor component is discharged by desorbing the odor component.   Provided with a flow path switching mechanism that is disposed downstream of the adsorbent holding mechanism of the air supply path and switches the flow path to the outdoor side, and if necessary, the flow of the air supply path is moved to the outdoor side by the flow path switching mechanism. 2. The humidifier according to claim 1, wherein the humidifier is configured to discharge the odor component by heating the adsorbent at a temperature equal to or higher than the temperature (T2) by the heating means in the air supply path and desorbing the odor component. .   A humidifying device that traps moisture and odor components with an adsorbent and humidifies the room with the trapped moisture, an exhaust passage that discharges indoor air to the outdoors, and indoor air that takes indoor air and returns it to the room again An adsorbent holding mechanism that positions and replaces a part of the adsorbent in each of the flow path, the exhaust path, and the indoor air flow path, and the upstream side of the adsorbent holding mechanism in the indoor air flow path And the adsorbent desorbs moisture by heating to a temperature (T1) or higher, and desorbs odor components by heating to a temperature (T2) higher than the temperature (T1). It is an adsorbent, and moisture is adsorbed by the adsorbent in the exhaust passage, and the adsorbent is heated to a temperature not lower than temperature (T1) and lower than temperature (T2) by the heating means in the indoor air flow path. Substantially by desorbing moisture without odor, humidifier, characterized by being made so as to perform a humidifying for indoor Te.   A second heating means disposed upstream of the adsorbent holding mechanism in the exhaust passage, and if necessary, the adsorbent is heated to a temperature (T2) or higher by the second heating means in the exhaust passage; The humidifier according to claim 4, wherein the odor component is discharged by desorbing the odor component.   A flow path switching mechanism that is disposed downstream of the adsorbent holding mechanism of the indoor air flow path and switches the flow path to the outdoor side is provided. If necessary, the flow of the indoor air flow path is controlled by the flow path switching mechanism. The odor component is discharged by heating the adsorbent to a temperature (T2) or higher by the heating means in the indoor air flow path and desorbing the odor component while switching to the outside. Humidifier.   A humidifier that captures moisture and odor components with an adsorbent and humidifies the room with the trapped moisture, and supplies the outdoor air to the room, and takes in the outdoor air and discharges it to the outdoors again. Arranged on the upstream side of the adsorbent holding mechanism in the air supply path, an adsorbent holding mechanism that positions and replaces a part of the adsorbent in each of the air supply path and the outside air flow path And the adsorbent desorbs moisture by heating to a temperature (T1) or higher, and desorbs odor components by heating to a temperature (T2) higher than the temperature (T1). The adsorbent is adsorbed by the adsorbent in the outside air flow path, and heated by the heating means to a temperature not lower than the temperature (T1) and lower than the temperature (T2) in the air supply path. Substantially odor Moisture by desorbing without humidifying apparatus characterized by being made so as to perform a humidifying for the room.   A second heating unit disposed upstream of the adsorbent holding mechanism of the outside air channel is provided, and if necessary, the adsorbent is heated to a temperature (T2) or higher by the second heating unit in the outside air channel. The humidifying device according to claim 7, wherein the odor component is discharged by desorbing the odor component.   Provided with a flow path switching mechanism that is disposed downstream of the adsorbent holding mechanism of the air supply path and switches the flow path to the outdoor side, and if necessary, the flow of the air supply path is moved to the outdoor side by the flow path switching mechanism. 8. The humidification according to claim 7, wherein the odorous component is discharged by switching and desorbing the odorous component by heating the adsorbent to a temperature (T2) or higher by the heating means in the air supply path. apparatus.   A humidifying device that traps moisture and odor components with an adsorbent and humidifies the room with the trapped moisture. An outside air passage that takes in outdoor air and discharges it to the outside again; From the indoor air flow path to return to, an adsorbent holding mechanism that positions and replaces a part of the adsorbent in each of the outside air flow path and the indoor air flow path, and the adsorbent holding mechanism of the indoor air flow path And heating means disposed upstream, the adsorbent desorbs moisture by heating to a temperature (T1) or higher, and heats to a temperature (T2) higher than the temperature (T1). An adsorbent that desorbs odor components, adsorbs moisture to the adsorbent in the outside air flow path, and is at or above the temperature (T1) and below the temperature (T2) by the heating means in the indoor air flow path By desorbing moisture is substantially free of odor by heating the adsorbent to a temperature, the humidification apparatus characterized by being made so as to perform a humidifying for the room.   A second heating means disposed upstream of the adsorbent holding mechanism of the outside air flow path, and if necessary, heats the adsorbent to a temperature (T2) or higher by the second heating means in the outside air flow path; The humidifier according to claim 10, wherein the odor component is discharged by desorbing the odor component.   A flow path switching mechanism that is disposed downstream of the adsorbent holding mechanism of the indoor air flow path and switches the flow path to the outdoor side is provided. If necessary, the flow of the indoor air flow path is controlled by the flow path switching mechanism. The odor component is discharged by switching to the outside and heating the adsorbent to a temperature (T2) or higher by the heating means in the indoor air flow path to desorb the odor component. Humidifier. The humidifier according to any one of claims 1 to 12, wherein the adsorbent has the characteristics described below.
Characteristics of adsorbent: The ratio of moisture desorption amount when heated from 25 ° C. to 100 ° C. is 60% or more with respect to the water vapor adsorption amount when water vapor is adsorbed in a dry state at 25 ° C., and 25 The ratio of the ammonia desorption amount when heated from 25 ° C. to 100 ° C. is 60% or less with respect to the ammonia adsorption amount when ammonia is adsorbed in a dry state at ° C.   The humidifier according to claim 13, wherein the adsorbent is AlPO-based zeolite.   A humidification method using the humidifier according to claim 1 to humidify a room.   A humidifier according to any one of claims 2, 3, 5, 6, 8, 9, 11, or 12 is used to humidify the room and, if necessary, discharge odor components adsorbed on the adsorbent to the outdoors. The humidification method characterized by performing.

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