JP2009198028A - Humidification device, and air conditioner with humidifying function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidification device and an air conditioner having a humidifying function capable of providing an air trunk of high sealing performance and little air leakage, and continuously supplying humidified air indoors by the simple motion of fixing a moisture adsorbing means holding an adsorbent material, and switching two sets of dampers disposed at its both sides. <P>SOLUTION: This humidification device comprises first and second air trunk dividing means 6, 7, and third and forth air trunk dividing means 8, 9 disposed by two layers at one side across the moisture adsorbing means 2 and having air trunk partitioning plates 10-13 dividing the air trunk into two, and first and second air trunk switching means 14, 15 disposed between the first and second air trunk dividing means, and between the third and forth air trunk dividing means, and having a pair of dampers and a pair of openings diagonally disposed. The moisture adsorbing means is fixed in the air trunk, and the air trunk partitioning plates 11, 12 of the second and third air trunk dividing means are closely kept into contact with surfaces of the moisture adsorbing means 2. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a humidifier using an adsorbent and an air conditioner having a humidifying function.

As a humidifier and an air conditioner equipped with a humidifier, there are the following.
The first conventional technique includes an outdoor unit as a non-feed water humidification unit that uses moisture in the outside air as humidified water, and alternately switches between the moisture absorption mode and the humidification mode. The room is humidified (see, for example, Patent Document 1).

  The second prior art is a humidifier comprising an adsorbent formed in a cylindrical shape, two air flow passages passing through the adsorbent, two air blowers installed in each air flow passage, and a heater. Install the device outside, rotate the adsorbent with a drive motor, pass through one air flow passage, exhaust the dry air with moisture adsorbed by the adsorbent to the outdoor, and pass through the other air flow passage and adsorb Humidified air in which moisture adsorbed on the material is evaporated is sent indoors to be humidified (see, for example, Patent Document 2).

In the third prior art, the humidification unit is configured integrally with the outdoor unit of the air conditioner, and inside the humidification unit, a disk-shaped rotary rotor in which an adsorbent is supported on a substrate formed in a honeycomb shape, Installed in a posture that crosses both the dehumidifying side passage and the regeneration side passage, the humidifying unit and the indoor unit are connected by an air duct, and the humidified air is transported indoors through this air duct, and is supported by the rotating rotor. As the adsorbent, a hydrophobic zeolite having a low adsorption energy is used, and the SiO ₂ molar fraction is larger than the Al ₂ O ₃ molar fraction, that is, the SiO ₂ / Al ₂ O ₃ is larger than 1. (For example, refer to Patent Document 3).

Japanese Patent Laid-Open No. 6-257805 (page 3 to page 4, FIGS. 1 and 4) JP-A-10-267331 (page 3 to page 4, FIG. 1) JP 2001-96126 A (page 3 to page 4, FIGS. 1 and 2)

  However, in the first prior art, since the moisture absorption mode and the humidification mode are alternately switched in the two non-feed water humidification units, humidified air can always be supplied into the room. The size is increased and the cost is increased. When switching modes, it is necessary to switch between the four-way solenoid valve, the two two-way solenoid valves, the two pumps, and to turn on / off the two heaters. There was a problem that many subjects were complicated. Also, since the heater is turned ON / OFF, when switching to the moisture absorption mode, high temperature air is sent until the heater cools down, so moisture absorption is not performed, while when switching to the humidification mode, the heater temperature Since the humidification is not performed until the start up, there is a problem that the time loss at the time of mode switching is large.

  In the second prior art, the adsorbent is rotated and the moisture in the outside air adsorbed in one air flow passage is evaporated in the other air flow passage and sent to the room. However, humidified air can be continuously supplied to the room, but in order to rotate the adsorbent installed across the two air flow passages, a gap must be installed in the vicinity of the adsorbent, There was a problem that air leakage occurred between the two air flow passages. Moreover, since the blower is installed outside, the influence of noise generated from the blower indoors can be reduced. However, since the direction of the air flow by the two blowers is the same, adsorption and desorption on the adsorbent Is performed in the parallel direction, the adsorption / desorption efficiency is lowered, and there is a problem that a sufficient amount of humidification cannot be obtained.

  In the third prior art, the humidifying unit is installed integrally with the outdoor unit, and the outdoor high-humidity air is adsorbed by the adsorbent. Therefore, the amount of adsorption is easier to secure than using indoor air, but the humidifying operation is performed. Since the dehumidifying side passage through which low-temperature air always flows and the humidifying side passage through which high-humidity air always flows are installed next to each other when the outside air to be performed is low temperature, dew condensation occurs in the humidifying side passage, and the humidified air Even in the air duct that conveys the air to the room, there is a problem that condensation occurs because it is cooled by the outside air. In addition, since hydrophobic zeolite with low adsorption energy is used as the adsorbent, zeolite has a smaller amount of adsorption than adsorbents such as silica gel and activated carbon, and in particular, hydrophobic zeolite has low adsorption energy but also has a small amount of adsorption. There was a problem that a sufficient amount of humidification could not be obtained.

  The present invention has been made in order to solve the above-described problems, by fixing the moisture adsorbing means carrying the adsorbent, and by switching between two sets of dampers installed on both sides thereof, The present invention provides a humidifier capable of realizing an air passage with high airtightness and less air leakage and capable of continuously supplying humidified air into a room, and an air conditioner having a humidifying function. In addition, by making the adsorption process and the regeneration process in the moisture adsorption means always counter flow, moisture adsorption and regeneration can be performed efficiently, and the adsorption and regeneration air paths are switched and specified. The air passage is not cooled, and a humidifier having a feature that condensation is unlikely to occur inside the humidifier and an air conditioner having a humidifier function are provided. Further, a humidifier having a large absolute humidification amount by using an adsorbent with a large adsorption amount and a small adsorption energy, or by combining a plurality of adsorbents having different adsorption characteristics by taking advantage of these characteristics, And an air conditioner having a humidifying function.

The humidifier according to the present invention includes a moisture adsorbing means carrying an adsorbent for adsorbing and regenerating moisture in the air, a heating means for heating the air flowing into the moisture adsorbing means, and sucking outside air, A humidifying device comprising: a first air blowing means that exhausts the outside through the adsorption means; and a second air blowing means that sucks outside air and blows the air into the room through the heating means and the moisture adsorption means,
1st and 2nd airway division means, 2nd layer installed on one side across the moisture adsorbing means, and having an airway partition plate that divides the airway into 2 parts, and 3rd and 4th airway divisions Means,
A pair of dampers and a pair of openings provided between the first and second air passage dividing means and between the third and fourth air passage dividing means and provided diagonally. And first and second air path switching means having
The moisture adsorption means is fixedly installed in the air passage,
The air passage partition plates of the second and third air passage dividing means are in close contact with the surface of the moisture adsorption means.

  In the humidifying device of the present invention, the moisture adsorbing means carrying the adsorbent is fixed in the air passage, and two layers of first and second air passage dividing means, and third and fourth air passages are provided on one side thereof. Dividing means, and the air passage partition plates of the second and third air passage dividing means are brought into close contact with the surface of the moisture adsorbing means, and further between the first air passage dividing means and the second air passage dividing means. And by a simple operation of switching the dampers of the two sets of air passage switching means installed between the third air passage dividing means and the fourth air passage dividing means, the airtightness is high and the air leakage is small. There is an effect that a humidifier capable of realizing an air path and capable of supplying humidified air continuously into a room is obtained.

Embodiment 1 FIG.
FIG. 1 is a schematic configuration diagram of a humidifier according to Embodiment 1 of the present invention.
The humidification unit 1 which is a humidifier is a configuration in which a moisture adsorbing means 2, a first blowing means 3, a second blowing means 4, and a heating means 5 are arranged as basic components. It has become. The moisture adsorbing means 2 has a cylindrical shape and is fixedly installed in the air passage. Also, as an adsorbent supported on the moisture adsorbing means 2, it is applied to a porous substrate made of, for example, zeolite, silica gel, activated carbon or the like. It has been treated or impregnated and has a breathable structure.

FIG. 2 is a detailed view showing the configuration of the air path passing through the moisture adsorbing means 2 and shows each component in an easy-to-understand manner, but in reality, adjacent components are in close contact with each other.
The air path passing through the moisture adsorbing means 2 has a structure in which the air path dividing means is arranged in two layers on one side across the moisture adsorbing means 2. That is, in this example, the structure has a total of four layers, ie, the upper two layers (first layer 6 and second layer 7) and the lower two layers (third layer 8 and fourth layer 9). Here, the first layer 6 is the first air path dividing means 70, the second layer 7 is the second air path dividing means 71, the third layer 8 is the third air path dividing means 72, and the fourth layer 9 is The fourth air path dividing means 73 is configured. In the following, the first to fourth air path dividing means 70 to 73 will be described as a first layer 6, a second layer 7, a third layer 8, and a fourth layer 9, respectively.

  The first layer 6 is the first air channel divider 10, the second layer 7 is the second air channel divider 11, the third layer 8 is the third air channel divider 12, and the fourth layer 9 is the fourth. The air passage partition plate 13 is provided, and the air passage is divided into two by the first to fourth air passage partition plates 10 to 13. At this time, the second air path partition plate 11 and the third air path partition plate 12 are arranged in parallel, and are installed in close contact with the surface of the moisture adsorption means 2. On the other hand, the first air path partition plate 10 of the first layer 6 and the fourth air path partition plate 13 of the fourth layer 9 arranged at positions away from the moisture adsorption means 2 are the second air path partition plates. 11 and the third air passage partition plate 12 are installed vertically. Accordingly, the second layer 7, the moisture adsorption means 2, and the third layer 8 are divided into two air paths in the same direction, and the first layer 6 and the fourth layer 9 are divided into two air paths in the direction perpendicular to them. Will be. That is, the air passage is divided into four circular sections.

  Further, between the first layer 6 and the second layer 7 and between the third layer 8 and the fourth layer 9, the first air path switching damper 14 (first air path switching means) and the first layer Two air path switching dampers 15 (second air path switching means) are installed. The first air path switching damper 14 and the second air path switching damper 15 each have a pair of diagonally provided dampers and a pair of openings, and the first air path switching damper. The damper 14 and the second air path switching damper 15 are installed diagonally at an angle different by 90 °. That is, each of the first air path switching damper 14 and the second air path switching damper 15 is diagonally centered on a fan-shaped (1/4 circle) flat plate having two central angles 90 ° as shown in the figure. It is made up of dampers in a form connected to each other, and is installed so that the fan-shaped portions are staggered. In other words, the first air path switching damper 14 has a configuration in which two flat quadrants, for example, the first quadrant and the third quadrant, are connected at the center so that the flat plate closes (occupies). On the other hand, the second air path switching damper 15 is connected in the center so that the flat plate closes (occupies) the second quadrant and the fourth quadrant. Thereby, the diagonal 2 area | region is made into the 1st air path among 4 area | regions formed by the 1st air path partition plate 10 and the 2nd air path partition plate 11 for every 1/4 circle of the upper air path side. The switching damper 14 is closed, and is formed by the third air passage partition plate 12 and the fourth air passage partition plate 13, and is 90 ° different from the upper portion in four quarters of the lower air passage side. The second air path switching damper 15 closes the diagonal 2 region. In the first layer 6, of the two air paths divided by the first air path partition plate 10, the first air inlet 16 and the second air blowing means are provided on the air path side communicating with the first air blowing means 3. A second exhaust port 19 is installed on the side of the air passage communicating with the air passage 4. Similarly, the first air blowing means 3 out of the two air passages divided by the fourth air passage partition plate 13 in the fourth layer 9. A first exhaust port 18 is provided on the side of the air passage communicating with the air passage, and a heating unit 5 and a second intake port 17 are provided on the side of the air passage communicating with the second air blowing unit 4. Note that the upper surface of the first layer 6 and the lower surface (bottom surface) of the fourth layer 9 are actually closed by a lid or the like (not shown), and the first air inlet 16 in the first layer 6 is closed to this lid. The second exhaust port 19 is provided, or the first intake port 16 and the second exhaust port 19 are provided on the side surface of the cylinder as illustrated. Similarly, in the fourth layer 9, the first exhaust port 18 and the second intake port 17 are provided on the bottom lid, or the first exhaust port 18 and the second exhaust port 17 are provided on the side surface of the cylinder as shown in the figure. An air inlet 17 is provided.

Next, an example of the operation will be described. For the sake of explanation, FIG. 3 shows a plan view of each air passage component shown in FIG. The damper position <A> on the left side in FIG. 3 is the same as the damper position in FIG.
At the damper position <A>, the outside air sucked from the first intake port 16 as the adsorption inlet air 20 enters the region 6b of the first layer 6 partitioned by the first air channel partition plate 10, and Since the region 14 c is closed by the one air path switching damper 14, the air flows into the second layer 7 through the opening 14 d. The second layer 7 is divided into semicircles by the second air passage partition plate 11, and the third layer 8 is divided into semicircles by the third air passage partition plate 12, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into semicircles, so that the outside air flowing in from the opening 14d flows downward in the order of the regions 7b, 2b, and 8b. Become. Since the area 15d of the outside air that has become dry air is blocked by the second air path switching damper 15, the area 15a of the fourth layer 9 partitioned by the fourth air path partition plate 13 from the opening 15b. Then, it flows out from the first exhaust port 18 as the adsorption outlet air 22, and is exhausted to the outside through the first blowing means 3.

  On the other hand, the outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into the region 9 b of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and is heated by the heating means 5. After the high-temperature and low-humidity air is formed, the region 15d is closed by the second air path switching damper 15, and therefore flows into the third layer 8 through the opening 15c. The third layer 8 is divided into semicircles by the third air passage partition plate 12 and the second layer 7 is divided into semicircles by the second air passage partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers. Is divided into semicircles similarly, the high-temperature and low-humidity air flowing in from the opening 15c flows upward in the order of the regions 8a, 2a, and 7a, and the moisture adsorbed when passing through the region 2a is regenerated. High humidity air. Since the area 14c is closed by the first air path switching damper 14, the outside air that has become the high humidity air is the area 6a of the first layer 6 that is partitioned by the first air path partition plate 10 from the opening 14a. And then flows out as regeneration outlet air 23 from the second exhaust port 19 and is transported into the room through the second blowing means 4 to humidify the room.

  Next, after a time has passed to complete the adsorption step in the region 2b of the moisture adsorption means 2 and the regeneration step in the region 2a, the damper position shown in FIG. 3 is switched from <A> to <B>. At this time, the outside air sucked from the first air inlet 16 as the adsorption inlet air 20 enters the region 6b of the first layer 6 partitioned by the first air passage partition plate 10, and the first air passage switching. Since the region 14 d is closed by the damper 14, it flows into the second layer 7 through the opening 14 c. The second layer 7 is divided into semicircles by the second air passage partition plate 11, and the third layer 8 is divided into semicircles by the third air passage partition plate 12, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into semicircles, the outside air flowing in from the opening 14c flows downward in the order of the regions 7a, 2a, 8a, and moisture is regenerated when the region 2a is at the damper position <A>. Since it is dry, moisture in the outside air is adsorbed when passing through the region 2a to become dry air. Since the area 15 c is closed by the second air path switching damper 15, the outside air that has become dry air passes from the opening 15 a to the area 9 a of the fourth layer 9 that is partitioned by the fourth air path partition plate 13. Then, it flows out from the first exhaust port 18 as the adsorption outlet air 22, and is exhausted to the outside through the first blowing means 3.

  On the other hand, the outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into 9 b of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and is heated by the heating means 5. After the air becomes high-temperature and low-humidity air, 15c is blocked by the second air path switching damper 15, and therefore flows into the third layer 8 from 15d. The third layer 8 is divided into semicircles by the third air passage partition plate 12 and the second layer 7 is divided into semicircles by the second air passage partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into semicircles, so the high-temperature and low-humidity air flowing in from 15d flows upward in the order of 8b, 2b, and 7b, and the moisture adsorbed at the damper position <A> when passing through 2b Regenerated to become highly humid air. Since the outside air that has become the high humidity air is blocked by the first air path switching damper 14, the outside air flows from 14 b to 6 a of the first layer 6 partitioned by the first air path partition plate 10, Thereafter, the air flows out from the second exhaust port 19 as the regeneration outlet air 23 and is transported into the room via the second air blowing means 4 to humidify the room.

  Thus, it is possible to supply humidified air continuously into the room by a simple operation of rotating the first air path switching damper 14 and the second air path switching damper 15 to switch the air path, Since the wind directions in the regions 2a and 2b of the moisture adsorbing means 2 are opposite, that is, the adsorption process and the regeneration process are counterflows, moisture adsorption and regeneration can be efficiently performed even if the thickness of the moisture adsorbing means 2 is increased. Can do. The optimum value for switching the air path differs depending on the type of adsorbent supported on the moisture adsorbing means 2, so that it is short (about 45 to 90 seconds) for a material having a relatively high adsorption rate such as zeolite. ) In the case of a material having a relatively low adsorption rate, such as silica gel, by setting it long (about 90 to 180 seconds), it is possible to perform an optimum operation for an adsorbent having various characteristics. Compared with the conventional rotor method in which the moisture adsorption means 2 is rotated, in the present embodiment, the moisture adsorption means 2 having the largest air leakage is fixed in the air passage, and the vicinity of the moisture adsorption means 2 is on the surface thereof. Since the second air passage partition plate 11 and the third air passage partition plate 12 are in close contact with each other, the air leakage can be minimized. Further, if a material having excellent flexibility such as urethane is added to the end surfaces of the first air path switching damper 14 and the second air path switching damper 15, the first air path switching damper 14 and the second air path switching damper 14 and the second air path switching damper 14 are provided. The air path switching damper 15 can be rotated with low torque, and air leakage can be suppressed to a smaller extent. Furthermore, in this embodiment, an adsorption air passage through which low-temperature air flows and a regeneration air passage through which high-temperature and high-humidity air flow are fixed at all times. Further, since the adsorption air passage and the regeneration air passage are switched and the specific air passage is not cooled, there is also a feature that condensation is hardly generated.

  Further, even if the first air path switching damper 14 and the second air path switching damper 15 are continuously rotated at a rotation angle of 90 ° in the same direction to switch the air path, they are rotated forward and reverse at a rotation angle of 90 °. May be repeated. In the case of the same direction, even if a central shaft is installed in the damper and the shaft is rotated, or a gear or the like is installed in the outer peripheral portion and rotated, the motor can be rotated by one, and the cost can be reduced. In the case of forward / reverse rotation, for example, as shown in FIG. 4, in the first air path switching damper 14 and the second air path switching damper 15, the second air path is formed on the entire radial portion at both ends of the sector plate. Protrusions 141 and 151 that contact the partition plate 11 and the third air passage partition plate 12 can be provided. Accordingly, the second air path partition plate 11 serves as a stopper in the first air path switching damper 14 and the third air path partition plate 12 serves as a stopper in the second air path switching damper 15, so that no rotation error occurs. At the same time, since the protruding portion and the partition plate are in close contact with each other over a wider area, air leakage can be prevented. In FIG. 4, the protruding portion is disposed toward the moisture adsorption means 2 side, but is disposed toward the opposite side of the moisture adsorption means 2, and the first air path switching damper 14 is the first air path partition. The plate 10 and the second air path switching damper 15 may be in close contact with the fourth air path partition plate 13.

  The thicknesses of the first layer 6 and the second layer 7, and the third layer 8 and the fourth layer 9 are the thicknesses of the first layer 6 and the fourth layer 9 where the air inlet and outlet are installed. The second layer 7 and the third layer 8 that are close to the moisture adsorbing means 2 may be thicker. When the first layer 6 and the fourth layer 9 are made thicker, the suction port and the outlet become larger and the air passage pressure loss becomes smaller, so that the blowing means can be made smaller. On the other hand, the second layer 7 and the third layer 8 When the thickness of the water adsorbing means 2 is increased, air easily flows through the entire moisture adsorbing means 2, so that the wind speed distribution is uniformed and the adsorbent supported on the entire moisture adsorbing means 2 can be used effectively. is there.

  In FIG. 1, the air blowing means is installed on the leeward side of the moisture adsorbing means 2, the first air blowing means 3 sends dry air from the first exhaust port 18, and the second air blowing means 4 comes from the second exhaust port 19. Although it is configured to suck out humidified air, it is installed on the windward side of the moisture adsorbing means 2, the first blowing means 3 is at the first intake port 16, and the second blowing means 4 is at the second intake port. It is good also as a structure which pushes external air into 17 each. When sucking out from the leeward side, the air passage pressure loss is reduced, so that the blower means can be reduced in size. When pushing in from the leeward side, the wind speed distribution in the moisture adsorbing means 2 is made uniform and supported by the entire moisture adsorbing means 2. There is an effect that the adsorbent made can be used effectively.

  In FIGS. 1 to 3, the first air inlet 16 is provided in the region 6 b of the first layer 6 and the second air is provided in the region 6 a so that the air flow directions of the adsorption step and the regeneration step in the moisture adsorption unit 2 are opposed to each other. The second intake port 17 is provided in the exhaust port 19 and the region 9b of the fourth layer 9, and the first exhaust port 18 is provided in the region 9a. The vertical position of the layer 9 may be reversed. In this case, since the heating means 5 is arranged in the uppermost layer, even if the adsorbent carried on the moisture adsorption means 2 is powdered, the possibility of reaching the heating means 5 is reduced, and safety is ensured. Can be increased. Further, for example, the second intake port 17 and the heating means 5 are installed in the region 6 a of the first layer 6, and the second exhaust port 19 is installed in the region 9 b of the fourth layer 9. The process may be performed in parallel flow. In this case, since the two suction ports are located in the same layer such as the first layer 6 and the two outlets are the fourth layer 9, the air blowing means is installed in the first layer 6, and the first Therefore, it is possible to push into both the air intake port 16 and the second air intake port 17, and it is possible to continuously generate humidified air with a single air blowing means.

  As described above, a simple operation of switching between the two rotary dampers can realize an air passage with high airtightness and less air leakage, and a humidifier that continuously supplies humid air to the room can be obtained. At this time, since the adsorption process and the regeneration process in the moisture adsorption means carrying the adsorbent are opposed to each other, moisture can be adsorbed and regenerated efficiently, resulting in a highly efficient humidifier. In addition, since the adsorption air passage and the regeneration air passage are switched and the specific air passage is not cooled, there is also an effect that it is difficult for condensation to occur in the humidifying device.

Embodiment 2. FIG.
FIG. 5 is a detailed view showing the configuration of the air path passing through the moisture adsorbing means 2 according to Embodiment 2 of the present invention, and is arranged inside the humidifier shown in FIG. In FIG. 5, each component is disassembled and shown in an easy-to-understand manner as in FIG. 2, but actually adjacent components are in close contact. The same parts and portions as those of the first embodiment are denoted by the same reference numerals and description thereof is omitted.
Of the two air passages divided by the first air passage divider 10 in the first layer 6 and the two air passages divided by the second air passage divider 11 in the second layer 7, the first air flow The first air inlet 16 on one side of the air passage communicating with the means 3 is arranged in a quarter circle region that is not blocked by the first air passage switching damper 14, that is, on one opening, and the first layer 6. The second exhaust port 19 on the other air passage side which is installed across the second layer 7 and communicates with the second air blowing means 4 is not blocked by the first air passage switching damper 14. It is installed in the 1/4 circle region, that is, the other opening, and straddling the two layers of the first layer 6 and the second layer 7. Of the two air passages divided by the third air passage divider 12 in the third layer 8 and the two air passages divided by the fourth air passage divider 13 in the fourth layer 9, respectively The first exhaust port 18 on the one air passage side communicating with the air blowing means 3 is arranged in a quarter circle region that is not closed by the second air passage switching damper 15, that is, in one opening portion, and in the third layer. The second air inlet 17 on the other air passage side which is installed across the two layers of 8 and the fourth layer 9 and communicates with the second air blowing means 4 is closed by the second air passage switching damper 15. It is installed in the 1/4 circle region that is not, that is, the other opening, and straddling the two layers of the third layer 8 and the fourth layer 9. In the fourth layer 9, the heating means 5 is installed on the air path side communicating with the second air blowing means 4 out of the two air paths divided by the fourth air path partition plate 13.

Next, an example of the operation will be described. For the sake of explanation, FIG. 6 shows a plan view of each air passage component shown in FIG. The damper position <A> on the left side in FIG. 6 is the same as the damper position in FIG.
At the damper position <A>, the first inlet 6 provided across the first layer 6, the opening 14 d of the first air path switching damper 14, and the second layer 7 serves as the adsorption inlet air 20. The sucked outside air is partitioned in the first layer 6 by the first air path partition plate 10 and thus in the area 6b, and in the first air path switching damper 14, the area 14c is closed and thus in the opening 14d. They flow in and are collected in the region 7b of the second layer 7 which is partitioned by the second airway partition plate 11. Similar to the second layer 7, the third layer 8 is divided into semicircles by the third airway partition plate 12, and the moisture adsorbing means 2 sandwiched between the two layers is also divided into semicircles. Therefore, the outside air collected in the region 7b flows downward in the order of the regions 2b and 8b, and moisture in the outside air is adsorbed when passing through the region 2b to become dry air. Since the area 15d is closed from the area 8b by the second air path switching damper 15, the fourth layer 9 partitioned from the area 8b by the fourth air path partition plate 13 from the area 8b. As the adsorption outlet air 22 from the first exhaust port 18 installed across the third layer 8, the opening 15 b of the second air path switching damper 15, and the fourth layer 9. It flows out and is exhausted to the outside via the first air blowing means 3.

  On the other hand, the outside air sucked as the regeneration inlet air 21 from the third layer 8, the opening 15c of the second air path switching damper 15, and the second intake port 17 installed across the fourth layer 9, The fourth layer 9 is partitioned by the fourth air path partition plate 13 and thus flows into the region 9b. In the second air path switching damper 15, the region 15d is closed and flows into the opening 15c. The third air path partition plate 12 partitions the third layer 8 area 8a. At this time, since the heating means 5 is installed in the region 9b, the outside air collected in the region 8a is heated to become high-temperature and low-humidity air. Similar to the third layer 8, the second layer 7 is divided into semicircles by the second air channel partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers is also divided into semicircles. Therefore, the high-temperature and low-humidity air collected in the region 8a flows upward in the order of the regions 2a and 7a, and the moisture adsorbed when passing through the region 2a is regenerated to become high-humidity air. Since the area 14c is blocked from the area 7a by the first air path switching damper 14, the outside air that has become the high humidity air is separated from the area 14a by the first air path partition plate 10 from the first layer. 6 and flows into the region 6a of the first regenerator outlet 23 from the second exhaust port 19 installed across the first layer 6, the opening 14a of the first air path switching damper 14, and the second layer 7. It flows out and is transported into the room via the second air blowing means 4 to humidify the room.

  Next, after the time for completing the adsorption process in the region 2b of the moisture adsorption means 2 and the regeneration process in the region 2a has elapsed, the damper position shown in FIG. 6 is switched from <A> to <B>. At this time, the outside air sucked as the suction inlet air 20 from the first inlet 6 installed across the first layer 6, the opening 14 c of the first air path switching damper 14, and the second layer 7 is The first layer 6 is partitioned by the first air path partition plate 10 so that it flows into the region 6b. In the first air path switching damper 14, the region 14d is closed, and therefore flows into the opening 14c. The second airflow partition plate 11 collects the region 7 a of the second layer 7. Similar to the second layer 7, the third layer 8 is divided into semicircles by the third airway partition plate 12, and the moisture adsorbing means 2 sandwiched between the two layers is also divided into semicircles. Therefore, the outside air collected in the region 7a flows downward in the order of the regions 2a and 8a, and since the moisture is regenerated and dried when the region 2a is at the damper position <A>, it passes through the region 2a. Sometimes moisture in the outside air is adsorbed and becomes dry air. Since the area 15c is closed from the area 8a by the second air path switching damper 15, the fourth layer 9 partitioned from the area 8a by the fourth air path partition plate 13 from the area 8a. As the adsorption outlet air 22 from the first exhaust port 18 installed across the third layer 8, the opening 15 a of the second air path switching damper 15, and the fourth layer 9. It flows out and is exhausted to the outside via the first air blowing means 3.

  On the other hand, the outside air sucked as the regeneration inlet air 21 from the third layer 8, the opening 15d of the second air path switching damper 15, and the second inlet 17 installed across the fourth layer 9, The fourth layer 9 is partitioned by the fourth air passage partition plate 13 and thus flows into the region 9b. In the second air passage switching damper 15, the region 15c is closed and flows into the opening 15d. 3 regions 8 b of the third layer 8 that are partitioned by the three air passage partition plates 12. At this time, since the heating means 5 is installed in the region 9b, the outside air collected in the region 8b is heated to become high-temperature and low-humidity air. Similar to the third layer 8, the second layer 7 is divided into semicircles by the second air channel partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers is also divided into semicircles. Therefore, the high-temperature and low-humidity air collected in the region 8b flows upward in the order of the regions 2b and 7b, and the moisture in the outside air adsorbed at the damper position <A> when the region 2b passes is regenerated. High humidity air. Since the area 14d is blocked from the area 7b by the first air path switching damper 14, the outside air that has become the high humidity air is separated from the area 14b by the first air path partition plate 10 through the first layer. 6, and the regeneration outlet air 23 from the second exhaust port 19 installed across the first layer 6, the opening 14 b of the first air path switching damper 14, and the second layer 7. It flows out and is transported into the room via the second air blowing means 4 to humidify the room.

  Thus, the first intake port 16 and the second exhaust port 19 are installed across the first layer 6 and the second layer 7, and the second intake port 17 and the first exhaust port 18 are connected to the first layer 6. The same effect as that of the first embodiment is obtained by installing over the third layer 8 and the fourth layer 9 and rotating together with the first air path switching damper 14 and the second air path switching damper 15 to switch the air path. In addition, since the air inlet / outlet to the air passage is large, the air passage pressure loss is small, the air blowing means can be downsized, and the air velocity distribution in the water adsorbing means 2 is made uniform, so that the entire water adsorbing means 2 is There is an effect that the adsorbent supported on the catalyst can be used effectively.

  Further, as in the first embodiment, the first air path switching damper 14 and the second air path switching damper 15 can be rotated even if they are continuously rotated at a rotation angle of 90 ° in the same direction to switch the air path. The forward / reverse rotation may be repeated at a rotation angle of °. In the case of the same direction, even if a central shaft is installed in the damper and the shaft is rotated, or a gear or the like is installed in the outer peripheral portion and rotated, the motor can be rotated by one, and the cost can be reduced. In the case of forward / reverse rotation, for example, as shown in FIG. 4, in the first air path switching damper 14 and the second air path switching damper 15, the second air path is formed on the entire radial portion at both ends of the sector plate. Protrusions 141 and 151 that contact the partition plate 11 and the third air passage partition plate 12 can be provided. Accordingly, the second air path partition plate 11 serves as a stopper in the first air path switching damper 14 and the third air path partition plate 12 serves as a stopper in the second air path switching damper 15, so that no rotation error occurs. At the same time, since the protruding portion and the partition plate are in close contact with each other over a wider area, air leakage can be prevented. In FIG. 4, the protruding portion is disposed toward the moisture adsorption means 2 side, but is disposed toward the opposite side of the moisture adsorption means 2, and the first air path switching damper 14 is the first air path partition. The plate 10 and the second air path switching damper 15 may be brought into contact with and in close contact with the fourth air path partition plate 13.

  In FIG. 6, the first intake port 16, the second intake port 17, the first exhaust port 18, the second exhaust port 19, the first air path switching damper 14 and the second air path switching damper 15. Are rotated by 90 ° in conjunction with each other to switch the air path. As shown in FIG. 7, the first air path switching damper 14 includes the first air path partition plate 10 and the second air path partition plate. 11, the second air path switching damper 15 is fixedly installed on the third air path partition plate 12 and the fourth air path partition plate 13, and the first air inlet 16 and the second air inlet 17. The first exhaust port 18 and the second exhaust port 19 may be continuously rotated 180 ° in the same direction to switch the air path, or forward and reverse rotation at an angle of 180 ° may be repeated. In this case, since the partition plate inside the air passage and the damper are completely brought into close contact with each other, it is possible to prevent air leakage without providing a projection or the like as shown in FIG.

  6 and 7, the first intake port 16 and the second exhaust port 19 are connected to the first layer 6 and the second layer so that the air flow directions of the adsorption step and the regeneration step in the moisture adsorption unit 2 are opposite to each other. The second intake port 17 and the first exhaust port 18 are installed across the third layer 8 and the fourth layer 9, but are in the same counterflow, and the first layer The upper and lower positions of 6 and the second layer 7, the third layer 8 and the fourth layer 9 may be reversed. In this case, since the heating means 5 is arranged in the uppermost layer, even if the adsorbent carried on the moisture adsorption means 2 is powdered, the possibility of reaching the heating means 5 is reduced, and safety is ensured. Can be increased. For example, at the damper position <A> in FIGS. 6 and 7, the second intake port 17 is provided in the region 6 a of the first layer 6, the opening 14 a of the first air path switching damper 14, and the region 7 a of the second layer 7. The heating means 5 is applied to the region 6a of the first layer 6, the region 8a of the third layer 8, the opening 15c of the second air path switching damper 15, and the second exhaust port 19 to the region 9b of the fourth layer 9. And the adsorption step and the regeneration step in the moisture adsorption means 2 may be performed in parallel flow. In this case, the two suction ports are located in the same layer such that the upper layer (first layer 6 to second layer 7) and the two outlets are lower layers (third layer 8 to fourth layer 9). Therefore, it is possible to install the air blowing means in the upper layer and push it into both the first air inlet 16 and the second air inlet 17, and humid air can be continuously generated by one air blowing means.

  As described above, the air passage with high airtightness and small air loss and pressure loss is achieved by the simple operation of installing the suction inlet and the air outlet over two layers and rotating with the two rotary dampers to switch the air passage. And a humidifier that continuously supplies humidified air into the room can be obtained. At this time, the wind speed distribution in the moisture adsorbing means is made uniform, and not only the adsorbent supported on the entire moisture adsorbing means 2 can be used effectively, but also the adsorption process and the regeneration process are counterflows. Can be efficiently adsorbed and regenerated, resulting in a highly efficient humidifier. In addition, since the adsorption air passage and the regeneration air passage are switched and the specific air passage is not cooled, there is also an effect that it is difficult for condensation to occur in the humidifying device.

Embodiment 3 FIG.
FIG. 8 is a schematic configuration diagram of the humidifier according to the embodiment of the present invention.
The humidification unit 1 which is a humidifier is a configuration in which a moisture adsorbing means 2, a first blowing means 3, a second blowing means 4, and a heating means 5 are arranged as basic components. It has become. The moisture adsorbing means 2 has a rectangular parallelepiped shape and is fixedly installed in the air passage. Further, as an adsorbent to be carried on the moisture adsorbing means 2, it is applied to a porous substrate made of, for example, zeolite, silica gel, activated carbon or the like. It has been treated or impregnated and has a breathable structure.

FIG. 9 is a detailed view showing the configuration of the air path passing through the moisture adsorbing means 2, which is arranged in order with the rear side facing up when FIG. 8 is viewed from above. As shown, the adjacent parts are actually in close contact.
The air passage passing through the moisture adsorption means 2 has a structure in which the air passage dividing means is arranged in two layers on the back side and the near side across the moisture adsorption means 2. That is, in this example, the structure has a total of four layers of two layers on the back side (first layer 6 and second layer 7) and two layers on the near side (third layer 8 and fourth layer 9). Here, the first layer 6 is the first air path dividing means 70, the second layer 7 is the second air path dividing means 71, the third layer 8 is the third air path dividing means 72, and the fourth layer 9 is The fourth air path dividing means 73 is configured. In the following, the first to fourth air path dividing means 70 to 73 will be described as a first layer 6, a second layer 7, a third layer 8, and a fourth layer 9, respectively.

  The first layer 6 is the first air channel divider 10, the second layer 7 is the second air channel divider 11, the third layer 8 is the third air channel divider 12, and the fourth layer 9 is the fourth. The air passage partition plate 13 is provided, and the air passage is divided into two by the first to fourth air passage partition plates 10 to 13. At this time, the second air path partition plate 11 and the third air path partition plate 12 are arranged in parallel, and are installed in close contact with the surface of the moisture adsorption means 2. On the other hand, the first air path partition plate 10 of the first layer 6 and the fourth air path partition plate 13 of the fourth layer 9 arranged at positions away from the moisture adsorption means 2 are the second air path partition plates. 11 and the third air passage partition plate 12 are installed vertically. Accordingly, the second layer 7, the moisture adsorption means 2, and the third layer 8 are divided into two air paths in the same direction, and the first layer 6 and the fourth layer 9 are divided into two air paths in the direction perpendicular to them. Will be. That is, the air path is divided into four square sections.

  Further, between the first layer 6 and the second layer 7, a first four air path partition plate 24 and a first air path switching damper 14 (first air path switching means) are installed. . Similarly, between the 3rd layer 8 and the 4th layer 9, the 2nd 4 air way partition plate 25 and the 2nd air way switching damper 15 (2nd air way switching means) are installed. Yes. Here, each of the first air path switching damper 14 and the second air path switching damper 15 is composed of an L-shaped plate, and is provided with a pair of dampers and a pair of openings provided diagonally. The first air path switching damper 14 and the second air path switching damper 15 are installed diagonally at an angle different by 90 °. That is, the first air path switching damper 14 and the second air path switching damper 15 are respectively connected to the second air path partition plate 11 of the second layer 7 and the third air path partition plate 12 of the third layer 8. As shown in the figure, two L-shaped plates are connected diagonally at the corners of the L-shape, and the one side plate is the second airway partition plate 11 and the third. The air passage partition plate 12 is formed in a linearly continuous form and is installed adjacent to each other with an angle difference of 90 °. Thus, the L-shaped side plate also serves as the first air path partition plate 11 and the second air path partition plate 12. In other words, the first air path switching damper 14 is connected at the center so that the L-shaped plate closes (occupies) two quadrants of the square, for example, the first quadrant and the third quadrant. In contrast to this, the second air path switching damper 15 is connected at the center so that the L-shaped plate closes (occupies) the second quadrant and the fourth quadrant. This is a form having a partition plate that divides the air passage into two. Thereby, the diagonal 2 area | region is comprised among the 4 area | regions of the back | inner side air path formed of the 1st air path partition plate 10, the 1st 4 air path partition plate 24, and the 2nd air path partition plate 11. The first air path switching damper 14 is closed, and the front side air path 4 formed by the third air path partition plate 12, the second 4 air path partition plate 25, and the fourth air path partition plate 13. In the region, the second air path switching damper 15 closes the diagonal two regions that are 90 ° different from the back side. In the first layer 6, one of the two air passages divided by the first air passage partition plate 10 is provided with the second air blowing means 4 and the second exhaust port 19, and the other first air blower. A first air inlet 16 is installed on the air passage side communicating with the means 3. Similarly, in the fourth layer 9, one of the two air passages divided by the fourth air passage partition plate 13 is the first air passage. The heating means 5 and the second air inlet 17 are installed on the air passage side where the air blowing means 3 and the first exhaust port 18 communicate with the other second air blowing means 4.

  Next, an example of the operation will be described. FIG. 10 shown for explanation is a plan view of each component shown in FIG. 9, and corresponds to a cross-sectional view of FIG. 8 arranged in order with the back side up. The damper position <A> on the left side in FIG. 10 is the same as the damper position in FIG. At the damper position <A>, the outside air sucked from the first intake port 16 as the adsorption inlet air 20 enters the region 6a of the first layer 6 partitioned by the first air channel partition plate 10, and Since the area 14 c is closed by the one air path switching damper 14, the air flows into the second layer 7 from the opening 14 a via the area 24 a where the first four air path partition plates 24 are installed. The second layer 7 is partitioned by the second air path partition plate 11, and the third layer 8 is partitioned by the third air path partition plate 12 into upper and lower halves, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into upper and lower halves, so that the outside air flowing in from the opening 14a flows to the front side (downward in FIG. 10) in the order of the regions 7a, 2a, and 8a, and in the outside air when passing through the region 2a. Moisture is adsorbed to form dry air. Since the area 15a is closed by the second air path switching damper 15, the outside air that has become dry air passes through the area 25b in which the second four air path partition plates 25 are installed from the opening 15b. Then, it flows into the region 9b of the fourth layer 9 partitioned by the fourth air passage partition plate 13, and is then exhausted to the outside as the adsorption outlet air 22 from the first exhaust port 18 by the first air blowing means 3. The

  On the other hand, the outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into the region 9 a of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and is heated by the heating means 5. Since the area 15a is closed by the second air path switching damper 15 after the air becomes high-temperature and low-humidity air, it is opened via the area 25c where the second 4-air path partition plate 25 is installed. It flows into the third layer 8 from the portion 15c. The third layer 8 is divided into upper and lower halves by the third air passage partition plate 12 and the second layer 7 is divided into the upper and lower halves by the second air passage partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into upper and lower halves, so the high-temperature and low-humidity air that has flowed from the opening 15c flows toward the back side (upward in FIG. 10) in the order of the regions 8b, 2b, and 7b, and is adsorbed when passing through the region 2b. Moisture that has been regenerated is converted to high-humidity air. Since the area 14c is blocked by the first air path switching damper 14, the outside air that has become the high humidity air passes through the area 24d where the first four air path partition plates 24 are installed from the opening 14d. Then, it flows into the region 6b of the first layer 6 partitioned by the first air passage partition plate 10, and then flows out as the regeneration outlet air 23 from the second exhaust port 19 by the second air blowing means 4. It is transported into the room and humidifies the room.

  Next, after the time for completing the adsorption step in the region 2a and the regeneration step in the region 2b of the moisture adsorption unit 2 has elapsed, the damper position shown in FIG. 10 is switched from <A> to <B>. At this time, the outside air sucked from the first air inlet 16 as the adsorption inlet air 20 enters the region 6a of the first layer 6 partitioned by the first air passage partition plate 10, and the first air passage switching. Since the region 14 a is closed by the damper 14, it flows into the second layer 7 through the opening 14 c via the region 24 c where the first four air passage partition plates 24 are installed. The second layer 7 is partitioned by the second air path partition plate 11, and the third layer 8 is partitioned by the third air path partition plate 12 into upper and lower halves, and the moisture adsorbing means 2 sandwiched between the two layers. Is divided into upper and lower halves similarly, the outside air flowing in from the opening 14c flows to the front side (downward in FIG. 10) in the order of the regions 7b, 2b, and 8b, and the region 2b has a damper position <A Since the moisture is regenerated and dried when>, moisture in the outside air is adsorbed when passing through the region 2b to become dry air. Since the area 15c is closed by the second air path switching damper 15, the outside air that has become dry air passes through the area 25d where the second four air path partition plates 25 are installed from the opening 15d. Then, it flows into the region 9b of the fourth layer 9 partitioned by the fourth air passage partition plate 13, and is then exhausted to the outside as the adsorption outlet air 22 from the first exhaust port 18 by the first air blowing means 3. The

  On the other hand, the outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into the region 9 a of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and is heated by the heating means 5. Since the area 15c is closed by the second air path switching damper 15 after the high temperature and low humidity air is formed, the air is opened through the area 25a where the second 4 air path partition plate 25 is installed. It flows into the third layer 8 from the portion 15a. The third layer 8 is divided into upper and lower halves by the third air passage partition plate 12 and the second layer 7 is divided into the upper and lower halves by the second air passage partition plate 11, and the moisture adsorbing means 2 sandwiched between the two layers. Is also divided into upper and lower halves, so that the high-temperature and low-humidity air that has flowed from the opening 15a flows to the back side (upward in FIG. 10) in the order of the regions 8a, 2a, and 7a, and the damper when passing through the region 2a The moisture adsorbed at the position <A> is regenerated to become highly humid air. Since the area 14a is blocked by the first air path switching damper 14, the outside air that has become the high humidity air passes through the area 24b in which the first four air path partition plates 24 are installed from the opening 14b. Then, it flows into the region 6b of the first layer 6 partitioned by the first air passage partition plate 10, and then flows out as the regeneration outlet air 23 from the second exhaust port 19 by the second air blowing means 4. It is transported into the room and humidifies the room.

  As described above, the moisture adsorbing means 2 has a rectangular parallelepiped shape, and the first air path switching damper 14 and the second air path switching damper 15 are L-shaped, so that the same effect as in the first embodiment can be obtained. In addition to being obtained, since all the parts are configured with straight lines, the manufacturing cost can be reduced. Furthermore, one side of the L-shaped portion of the first air path switching damper 14 and the second air path switching damper 15 also serves as the second air path partition plate 11 and the third air path partition plate 12. The number of parts can be reduced and the material cost can be reduced. In addition, since the air path can be switched by a simple operation of repeating forward and reverse at a rotation angle of 90 °, if a material having excellent flexibility such as urethane is added to the L-shaped end face, The additional material is brought into close contact with the air passage and becomes a stopper for switching operation, so that no operation error occurs and air leakage can be minimized.

  The thicknesses of the first layer 6 and the second layer 7, and the third layer 8 and the fourth layer 9 are the thicknesses of the first layer 6 and the fourth layer 9 where the air inlet and outlet are installed. The second layer 7 and the third layer 8 that are close to the moisture adsorbing means 2 may be thicker. When the first layer 6 and the fourth layer 9 are made thicker, the layer with the air going in and out becomes larger and the air passage pressure loss becomes smaller, so that the blowing means can be miniaturized. On the other hand, the second layer 7 and the third layer When 8 is thickened, air easily flows through the entire moisture adsorbing means 2, so that the wind speed distribution is made uniform, and the adsorbent supported by the entire moisture adsorbing means 2 can be used effectively. There is.

  8 to 10, the air blowing means is installed on the leeward side of the moisture adsorbing means 2, the dry air is supplied from the first air outlet 18 by the first air blowing means 3, and the second air outlet by the second air blowing means 4. The humidified air is sucked out from 19, but it is installed on the windward side of the moisture adsorbing means 2, the first blowing means 3 is at the first intake port 16, and the second blowing means 4 is at the second position. A configuration may be adopted in which outside air is pushed into the intake port 17. When sucking out from the leeward side, the air passage pressure loss is reduced, so that the blower means can be reduced in size. When pushing in from the leeward side, the wind speed distribution in the moisture adsorbing means 2 is made uniform and supported by the entire moisture adsorbing means 2. There is an effect that the adsorbent made can be used effectively.

  8 to 10, the first intake port 16 is provided in the region 6 a of the first layer 6, and the second is provided in the region 6 b so that the air flow directions in the moisture adsorption means 2 are opposite to each other in the regeneration step. The exhaust port 19 and the second air blowing means 4, the second air inlet 17 and the heating means 5 in the region 9 a of the fourth layer 9, and the first air outlet 18 and the first air blowing device 3 in the region 9 b. For example, the second intake port 17 and the heating means 5 are installed in the region 6b of the first layer 6 and the second exhaust port 19 is installed in the region 9a of the fourth layer 9, so that the moisture adsorbing unit 2 The adsorption step and the regeneration step may be performed in parallel flow. In this case, since the two suction ports are located in the same layer such as the first layer 6 and the two outlets are the fourth layer 9, the air blowing means is installed in the first layer 6, and the first Therefore, it is possible to push into both the air intake port 16 and the second air intake port 17, and it is possible to continuously generate humidified air with a single air blowing means.

  As described above, the moisture adsorbing means has a rectangular parallelepiped shape, and the air path switching damper has an L-shape, so that all parts are configured in a straight line, and the damper also serves as the air path partition plate. It is possible to obtain a low-cost humidifying device that continuously supplies humidified air into a room through an air passage having high performance and low air leakage. At this time, since the adsorption process and the regeneration process in the moisture adsorption means carrying the adsorbent are opposed to each other, moisture can be adsorbed and regenerated efficiently, resulting in a highly efficient humidifier. In addition, since the adsorption air passage and the regeneration air passage are switched and the specific air passage is not cooled, there is also an effect that it is difficult for condensation to occur in the humidifying device.

Embodiment 4 FIG.
FIG. 11 is a schematic configuration diagram of the outdoor side of the air conditioner having a humidifying function according to the fourth embodiment of the present invention. The humidifying unit 1 described in the first embodiment is replaced with the outdoor unit 26 of the air conditioner. It is installed in the upper part. Inside the outdoor unit 26, as is well known, a compressor 27, an outdoor unit heat exchanger 28, an outdoor unit blower 29, an expansion valve 30 and the like are installed and connected to a heat exchanger of an indoor unit (not shown) A heat pump cycle is formed. Since the humidification unit 1 is the same as that of the first embodiment, the description thereof is omitted.

  Next, an example of the operation will be described. Regarding the operation, the inside of the humidifying unit 1 is the same as that of the first embodiment, and thus the description thereof is omitted. When the heat pump cycle performs the heating operation, as described in the first embodiment, the first air path switching damper 14 and the second air path switching damper 14 and the second air current switching damper 14 are set so that the damper positions <A> and <B> in FIG. By repeatedly switching the air path switching damper 15, the adsorption outlet air 22 that is dry air and the regeneration outlet air 23 that is high-temperature and high-humidity air are continuously discharged from the humidification unit 1. At this time, since the humidification unit 1 is installed integrally with the upper part of the outdoor unit 26, the adsorption outlet air 22 is exhausted in the vicinity of the air inlet of the outdoor unit heat exchanger 28. On the other hand, the regeneration outlet air 23 is conveyed into the room by the second air blowing means 4 via a duct connecting the room and the outside, and is supplied to the room together with the high-temperature air discharged from the indoor unit. Heat and humidify.

  Thus, the air conditioning which has a humidification function is ensured by installing the humidification unit 1 in the upper part of the outdoor unit 26 of an air conditioner, without securing the floor space for newly installing the humidification unit 1. You can get a chance. Moreover, since it becomes possible to supply humidified air continuously indoors simultaneously with the heating operation of a heat pump cycle, the effect that the drying at the time of heating can be prevented is acquired. Further, since the adsorption outlet air 22 that is dry air and has a temperature slightly higher than the outside air due to adsorption heat is sucked into the outdoor unit heat exchanger 28 that is an evaporator during the heating operation of the heat pump cycle, The effect of suppressing frost formation in the machine heat exchanger 28 and improving the heating operation efficiency can also be expected.

  In FIG. 11, the humidification unit 1 is integrated and installed on the upper part of the outdoor unit 26 of the air conditioner. However, if the humidifying unit 1 is in a position that does not hinder the ventilation of the outdoor unit blower 29, You may install it integrally. In either case, it is possible to guide the regeneration outlet air 23 into the room and the adsorption outlet air 22 to the vicinity of the air inlet of the outdoor unit heat exchanger 28, and the installation floor space does not change when installed on the bottom surface. The same effect as that obtained when the humidifying unit 1 is installed integrally at the upper part can be obtained.

  In FIG. 11, the first air blowing means 3 is installed exclusively for exhausting the adsorption outlet air 22, but the humidifying unit 1 is installed integrally with the outdoor unit 26 of the air conditioner, so that FIG. 1, the first exhaust port 18 is installed on the lower surface of the region 9 a of the fourth layer 9, and the communication port is provided on the upper surface of the outdoor unit 26, so that the outdoor unit blower 29 is also used as the first blowing unit 3. Also good. In this case, since only the 2nd ventilation means 4 should be installed in the humidification unit 1, the number of blowers can be reduced and it becomes low cost.

  In FIG. 11, the humidification unit 1 described in the first embodiment is integrated and installed in the outdoor unit 26 of the air conditioner. However, the suction port (intake port) and the blowout port (exhaust port) have two layers. In Embodiment 2 in which the air path is switched by rotating with two rotary dampers, or in the third embodiment in which the moisture adsorption means 2 has a rectangular parallelepiped shape and the air path switching damper has an L shape. You may install the humidification unit 1 demonstrated. In either case, the regeneration outlet air 23 can be guided indoors, and the adsorption outlet air 22 can be guided near the air inlet of the outdoor unit heat exchanger 28. Therefore, the humidifying unit 1 described in the first embodiment is installed. The same effect as that obtained can be obtained.

  As described above, the humidification unit can be installed in an outdoor unit of an air conditioner and humidified simultaneously with the heating operation of the heat pump cycle to save space and prevent drying during heating. An air conditioner having a function can be obtained. At this time, the air dehumidified in the moisture adsorption means and the air whose temperature is slightly higher than the outside air due to the heat of adsorption is sucked into the outdoor unit heat exchanger, which is an evaporator, so frost formation in the outdoor unit heat exchanger The effect of suppressing the heating and improving the heating operation efficiency can also be expected.

Embodiment 5 FIG.
FIG. 12 is a schematic installation diagram of a humidifying device in an air conditioner having a humidifying function according to Embodiment 5 of the present invention, in which the humidifying unit 1 described in Embodiment 1 is installed on an outer wall 31 of a building. It is. Although not shown for each component in the heat pump cycle of the air conditioner, the refrigerant pipe connecting the outdoor unit and the indoor unit is installed through the wall hole 32, and the first exhaust port 18 of the humidifying unit 1 The outdoor exhaust port 33 that communicates with the second exhaust port 19 is open to the outside, and the indoor connection port 34 that communicates with the second exhaust port 19 faces and is in close contact with the wall hole 32. Since the humidification unit 1 is the same as that of the first embodiment, the description thereof is omitted.

  Next, an example of the operation will be described. Regarding the operation, the inside of the humidifying unit 1 is the same as that of the first embodiment, and thus the description thereof is omitted. When the heat pump cycle performs the heating operation, as described in the first embodiment, the first air path switching damper 14 and the second air path switching damper 14 and the second air current switching damper 14 are set so that the damper positions <A> and <B> in FIG. By repeatedly switching the air path switching damper 15, the adsorption outlet air 22 that is dry air and the regeneration outlet air 23 that is high-temperature and high-humidity air are continuously discharged from the humidification unit 1. At this time, the humidifying unit 1 is directly installed on the outer wall 31 of the building, and the indoor connection port 34 is in close contact with the wall hole 32. Therefore, the regeneration outlet air 23 does not pass through a duct or the like, and is supplied to the second blowing means. 4 is carried into the room at the shortest distance and supplied to the room together with the high-temperature air discharged from the indoor unit to heat and humidify the room.

  In this way, the humidification unit 1 is directly installed on the outer wall 31 of the building, and the indoor connection port 34 is brought into close contact with the wall hole 32, thereby eliminating the need for a duct for transporting the regeneration outlet air 23 into the room and reducing the cost. In addition to being able to reduce the air transport pressure, the air path pressure loss and noise are reduced, the second air blowing means 4 can be reduced in size, and the air having a highly reliable and compact humidification function can be obtained. A harmony machine can be obtained. Further, when the regeneration outlet air 23 having high humidity is conveyed by a duct, the duct is cooled by the outside air particularly in winter, so there is a high risk of condensation inside, but the humidification unit 1 is not necessary because the duct is unnecessary. It becomes possible to supply the humidified air generated in step 1 to the room effectively without loss. Moreover, since it becomes possible to supply humidified air continuously indoors simultaneously with the heating operation of a heat pump cycle, the effect that the drying at the time of heating can be prevented is acquired.

  In FIG. 12, although the outdoor exhaust port 33 is installed in the side surface of the humidification unit 1 and the adsorption outlet air 22 is open to the outside air, the vicinity of the air intake port of the outdoor unit heat exchanger of the air conditioner from the outdoor exhaust port 33 It is also possible to provide an air passage that leads to the outside and suck the suction outlet air 22 into the outdoor unit. In this case, since the adsorption outlet air 22 is dry and the temperature is slightly higher than the outside air due to adsorption heat, frost formation in the outdoor unit heat exchanger, which is an evaporator, is suppressed during heating operation, and heating operation efficiency is improved. The effect of improving can also be expected.

  Moreover, in FIG. 12, although the humidification unit 1 demonstrated in Embodiment 1 is installed in the outer wall 31 of a building, a suction inlet (a 1st inlet port and a 2nd inlet port), a blower outlet (1st Embodiment 2 in which the exhaust port and the second exhaust port) are installed across two layers and rotated together with the two rotary dampers to switch the air path, and the moisture adsorbing means 2 has a rectangular parallelepiped shape, and the air path switching damper The humidifying unit 1 described in the third embodiment may be installed in an L shape. In either case, if the indoor connection port 34 is brought into close contact with the wall hole 32 and the regeneration outlet air 23 is supplied to the room at the shortest distance, the same effect as the case where the humidification unit 1 described in the first embodiment is installed is obtained. can get.

  As described above, the humidification unit is installed directly on the outer wall of the building, and at the same time as the heating operation of the heat pump cycle, humidified air is supplied into the room at the shortest distance from the wall hole, so that drying during heating can be performed at low cost. It is possible to obtain an air conditioner having a highly efficient humidification function that can be prevented. At this time, since a duct for transporting humidified air from the outside to the room is not required, not only the air passage pressure loss is small and the air blowing means can be reduced, but also problems such as duct noise and condensation in the duct can be avoided. Thus, the effect of ensuring reliability can be obtained.

Embodiment 6 FIG.
FIG. 13 is a schematic installation diagram of a humidifying device in an air conditioner having a humidifying function according to Embodiment 6 of the present invention, in which the humidifying unit 1 described in Embodiment 1 is installed on an inner wall 35 of a building. It is. Although not shown for each component in the heat pump cycle of the air conditioner, the refrigerant pipe connecting the outdoor unit and the indoor unit is installed through the wall hole 32, and the first exhaust port 18 of the humidifying unit 1 The outdoor exhaust port 33 that communicates with the wall hole 32 faces and is in close contact with it, and the indoor connection port 34 that communicates with the second exhaust port 19 is open indoors. Since the humidification unit 1 is the same as that of the first embodiment, the description thereof is omitted.

  Next, an example of the operation will be described. Regarding the operation, the inside of the humidifying unit 1 is basically the same as that of the first embodiment, and thus the description thereof is omitted. However, the suction inlet air 20 sucked from the first intake port 16 and the second intake port 17 are omitted. The regeneration inlet air 21 sucked from the air becomes room air instead of outside air. When the heat pump cycle performs the heating operation, as described in the first embodiment, the first air path switching damper 14 and the second air path switching damper 14 and the second air current switching damper 14 are set so that the damper positions <A> and <B> in FIG. By repeatedly switching the air path switching damper 15, the adsorption outlet air 22 that is dry air and the regeneration outlet air 23 that is high-temperature and high-humidity air are continuously discharged from the humidification unit 1. At this time, the humidifying unit 1 is directly installed on the inner wall 35 of the building, and the indoor connection port 34 is open to the room, so that the regeneration outlet air 23 is not passed through a duct or the like by the second blowing means 4. The room is heated and humidified together with the high-temperature air supplied directly into the room and discharged from the indoor unit.

  In this manner, the humidifying unit 1 is directly installed on the inner wall 35 of the building, and the indoor connection port 34 is opened indoors, so that the duct for transporting the regeneration outlet air 23 into the room as in the fifth embodiment. Is not necessary, and it is possible to obtain a compact air conditioner having a humidifying function by reducing the size of the second blowing means 4 at a low cost, and avoid problems such as duct noise and condensation in the duct. This also makes it possible to obtain the effect of ensuring reliability. Also, since indoor air is used as the adsorption inlet air 20, air below room temperature does not flow inside the humidifying unit 1, and condensation occurs in the unit rather than when outside air flows through the adsorption air passage. The effect that it can be solved is obtained. Furthermore, since heated indoor air is used as the regeneration inlet air 21, the heating means 5 reduces the amount of heat necessary for raising the temperature in order to obtain the air temperature necessary for moisture regeneration in the moisture adsorption means 2. The energy saving effect is also obtained. Moreover, since it becomes possible to supply humidified air continuously indoors simultaneously with the heating operation of a heat pump cycle, the effect that the drying at the time of heating can be prevented is acquired.

  In FIG. 13, the first intake port 16 is opened indoors, and the heated indoor air is sucked as the adsorption inlet air 20. For example, the wall hole 32 is divided into two parts, and one of them is the first intake port. 16 or by providing another wall hole and connecting to the first intake port 16, external air may be sucked as the adsorption inlet air 20. In this case, since the adsorbent carried by the moisture adsorbing means 2 adsorbs moisture in the outside air having a high relative humidity, the amount of moisture that can be adsorbed by the adsorbent increases, so that the room air can be adsorbed rather than adsorbed indoor air. The effect of increasing the amount of humidification supplied to is obtained.

  In FIG. 13, the humidifying unit 1 described in the first embodiment is installed on the inner wall 35 of the building, but the inlet and outlet are installed across two layers and rotated together with two rotary dampers. Thus, the humidification unit 1 described in the second embodiment for switching the air path and the third embodiment in which the moisture adsorbing means 2 has a rectangular parallelepiped shape and the air path switching damper has an L-shape may be installed. In either case, if the indoor connection port 34 is opened to the room and the regeneration outlet air 23 is directly supplied to the room, the same effect as the case where the humidification unit 1 described in the first embodiment is installed can be obtained.

  As described above, by installing the humidification unit directly on the inner wall of the building and supplying the humidified air directly into the room at the same time as the heating operation of the heat pump cycle, it is possible to prevent low-cost and compact drying during heating. It is possible not only to obtain an air conditioner having a humidifying function that can be performed, but also to avoid problems such as duct noise and condensation in the duct, and an effect of ensuring reliability can be obtained. At this time, since heated indoor air is used as the adsorption inlet air and the regeneration inlet air, dew condensation inside the humidifying unit can be avoided, and energy input in the heating means necessary for the regeneration air generation can be reduced. An effect is also obtained.

Embodiment 7 FIG.
FIG. 14 is a conceptual diagram of isothermal adsorption lines of various adsorbents carried on the moisture adsorption means according to Embodiment 7 of the present invention, 36 is a general zeolite, 37 is 1.5 to 2.5 nm ( The first adsorbent which is a porous silicon material provided with a large number of pores of about nanometers), and 38 is the isothermal of a second adsorbent which is a zeolite-based material provided with a large number of pores of about 0.7 nm. An adsorption line is shown. In FIG. 14, the horizontal axis represents the relative humidity of the target air, and the vertical axis represents the equilibrium adsorption amount of moisture. In FIG. 14, the change rate of the equilibrium adsorption amount of water with respect to the relative humidity in the range where the relative humidity of the air is equal to or lower than the 0th relative humidity 39 (Φ0), as indicated by a general isothermal adsorption line 36 of zeolite. Is greater than the slope in the range above the zero relative humidity 39, and the zero relative humidity 39 is typically less than 10%. Further, as shown in the isothermal adsorption line 37 of the first adsorbent, the first adsorbent used in the present embodiment is the first relative humidity in which the relative humidity of air is greater than the zero relative humidity 39. The slope, which is the rate of change of the equilibrium adsorption amount of water with respect to the relative humidity in the range of 40 (Φ1) to the second relative humidity 41 (Φ2), is less than the first relative humidity 40 or exceeds the second relative humidity 41 Greater than the slope at. The first relative humidity 40 and the second relative humidity 41 are increased or decreased in the range of 30% to 60% by increasing or decreasing the pore diameter of the porous silicon material that is the first adsorbent. At this time, the equilibrium adsorption amount 44 (q1) at the first relative humidity is smaller than the equilibrium adsorption amount 43 (q0) at the zero relative humidity, and the equilibrium adsorption amount 45 (at the second relative humidity) ( q2) is larger than the equilibrium adsorption amount 43 (q0) at the 0th relative humidity.

  Similarly, as shown in the isothermal adsorption line 38 of the second adsorbent, the second adsorbent used in the present embodiment has an air relative humidity of the third relative humidity 42 (Φ3) or less. The slope that is the rate of change of the equilibrium adsorption amount of moisture relative to the relative humidity in the range is larger than the slope in the range that exceeds the third relative humidity 42. At this time, the third relative humidity 42 is larger than the zero relative humidity 39 and smaller than the first relative humidity 40, and the equilibrium adsorption amount 46 (q3) at the third relative humidity is the zeroth relative humidity. Greater than 43 (q0) of equilibrium adsorption at relative humidity.

  FIG. 15 is a conceptual diagram of an isothermal adsorption line of an adsorbent obtained by mixing silica gel and zeolite and changing their blending ratio, which is supported on a moisture adsorption means, as in FIG. 14, and 47 is 100% silica gel. , 48 is 100% zeolite, 49 is an isothermal adsorption line of a third adsorbent synthesized by mixing zeolite and silica gel and increasing the blending ratio of zeolite. In FIG. 15, the horizontal axis represents the relative humidity of the target air, and the vertical axis represents the equilibrium adsorption amount of moisture. The isothermal adsorption line 47 of 100% silica gel and the isothermal adsorption line 48 of 100% zeolite overlap with the fourth relative humidity 50 (Φ4), which is generally about 60%, and the isothermal adsorption line 49 of the third adsorbent. As shown, the equilibrium adsorption amount of the third adsorbent is greater than 100% silica gel in the relative humidity range below the fourth relative humidity 50, and zeolite in the relative humidity range above the fourth relative humidity 50. More than 100%.

  FIG. 16 is a schematic diagram showing the analysis results of the adsorption energy distribution by each terminal cation species of zeolite in the present embodiment. (A) is the terminal cation Na (sodium), (b) is the terminal cation K ( (Potassium) distribution. In FIG. 16, the horizontal axis represents the adsorption energy, and the vertical axis represents the integrated value of the amount of adsorbed water. The amount of water adsorbed by each adsorbing energy is shown integrated from the smaller adsorbing energy. Each line in the figure is a distribution in which 51 is small in SiO 2 / Al 2 O 3 (≈2.5), 52 is in SiO 2 / Al 2 O 3 (≈3.5), and 53 is large in SiO 2 / Al 2 O 3 (≈5.0). The smaller SiO2 / Al2O3 indicates that more moisture is adsorbed with lower adsorption energy. Note that SiO2 / Al2O3 represents the ratio of the molar fraction of SiO2 to the molar fraction of Al2O3.

Next, an example of the operation will be described. Description will be made assuming that an adsorbent having an isothermal adsorption line as shown in FIG. 14 is carried on the moisture adsorption means 2 of FIG. 11 described in the fourth embodiment. Since the operation inside the humidifying unit 1 is the same as that of the first embodiment, a detailed description thereof will be omitted.
Since the operation of the humidifying unit 1 is generally required when the room is dried during heating in winter, the outdoor air is at a low temperature (for example, 7 ° C./87% RH under the heating standard condition). When the heat pump cycle performs the heating operation, as described in the first embodiment, the first air path switching damper 14 and the second air path switching damper 14 and the second air current switching damper 14 are set so that the damper positions <A> and <B> in FIG. By repeatedly switching the air path switching damper 15, the adsorption outlet air 22 that is dry air and the regeneration outlet air 23 that is high-temperature and high-humidity air are continuously discharged from the humidification unit 1. At this time, since the humidification unit 1 is installed integrally with the upper part of the outdoor unit 26, the adsorption outlet air 22 is exhausted in the vicinity of the air inlet of the outdoor unit heat exchanger 28. One regeneration outlet air 23 is conveyed into the room by the second blowing means 4 via a duct connecting the room and the outside, and is supplied to the room together with the high-temperature air discharged from the indoor unit. Heat and humidify.

  At this time, when the first adsorbent having the isothermal adsorption line 37 is carried on the moisture adsorbing means 2, the region 2b at the damper position <A> and the region 2a at the damper position <B>, which are the adsorption process. In the relative humidity of the inlet air from 87% to Φ2 (41) up to the equilibrium adsorption amount q2 (45), the general zeolite (isothermal adsorption line 36) that adsorbs only the equilibrium adsorption amount q0 (43). ) Significantly increases the amount of adsorption. On the other hand, in the region 2a at the damper position <A> and the region 2b at the damper position <B>, which are regeneration steps, sufficient regeneration can be achieved if the relative humidity of the regeneration inlet air is set to Φ1 (40) or less. , By adjusting the pore diameter of the porous silicon material as the first adsorbent so that Φ1 (40) is about 40%, low temperature regeneration, for example, air heated to about 20 ° C. by the heating means 5 When used as regeneration air, a humidification amount corresponding to a large adsorption amount difference of q2-q1 can be obtained, and an energy saving effect that the amount of heat necessary for heating is reduced by the heating means 5 can be obtained. Similarly, when the moisture adsorbing means 2 carries the second adsorbent having the isothermal adsorption line 38, the region 2b at the damper position <A> and the region 2a at the damper position <B>, which are the adsorption process. , The adsorption is up to the equilibrium adsorption amount q3 (46) over a wide range from 87% relative humidity to Φ3 (42), so it is significantly adsorbed compared to the general zeolite that adsorbs only the equilibrium adsorption amount q0 (43). The amount increases. On the other hand, in the region 2a at the damper position <A> and the region 2b at the damper position <B>, which are regeneration steps, sufficient regeneration is possible if the relative humidity of the regeneration inlet air is set to Φ3 (42) or less. , The regeneration temperature can be reduced at a lower temperature compared to the general zeolite that has to raise the regeneration temperature to Φ0 (39) or less, so energy saving effect is obtained, and the amount of humidification is increased according to the difference in adsorption amount of q3-q0 Can be made.

  Further, when the moisture adsorbing means 2 carries the third adsorbent having the isothermal adsorption line 49 shown in FIG. 15, the adsorption characteristics of both silica gel and zeolite are utilized. As a general property of the adsorbent, silica gel has a large amount of adsorption at high humidity as shown by an isothermal adsorption line 47, and zeolite has an almost constant adsorption amount in a wide humidity range as shown by an isothermal adsorption line 48. In addition, the reaction speed of adsorption and regeneration is fast. Accordingly, in the region 2b at the damper position <A> and the region 2a at the damper position <B>, which are adsorption steps, the silica gel adsorption characteristics in the range of Φ4 (50) from the relative humidity of the inlet air. Therefore, the adsorption amount is larger than that of zeolite, and in the relative humidity range lower than Φ4 (50), the adsorption amount is not lowered as much as silica gel due to the adsorption characteristics of zeolite, and it is possible to cope with a wider humidity range. On the other hand, in the region 2a at the damper position <A> and the region 2b at the damper position <B>, which are regeneration steps, the amount of adsorption is smaller than that of zeolite due to the adsorption characteristics of silica gel. Reproduction is possible, and an energy saving effect is obtained. Here, it is possible to change the blending ratio for synthesizing zeolite and silica gel according to the application. For example, by setting the blending ratio of zeolite and silica gel to about 8: 2 or 7: 3, the speed of adsorption and regeneration. Is improved by about 20%, and higher humidification performance can be secured.

  Further, the adsorption energy distribution in FIG. 16 is obtained by integrating the adsorption amount from the smaller adsorption energy on the left side in the figure. When the terminal cation in (a) is Na, the adsorption energy at which moisture is adsorbed. Is over a wide range up to 40 kcal / mol or more, whereas when the terminal cation of (b) is K, it is adsorbed only in the range of 20 kcal / mol or less. This is thought to be due to the position where water molecules adsorb to the zeolite. That is, in the case of the K cation, it is only adsorption to the six-membered ring of oxygen having a small adsorption energy called pore feeling, but in the case of the Na cation, the water molecule adsorbed to the cation species electrostatic field having a large adsorption energy. Because there is also. Here, for example, in order to secure a humidification amount of 1 L / h, the adsorption energy that can be desorbed by the heating means having a heating capacity of 1 kW is estimated to be about 13 kcal / mol, and about 1 kW for moisture adsorbed with more energy than this. This heating means does not desorb. Therefore, in the adsorption energy distribution of Na cations in FIG. 16 (a), moisture adsorbed with an energy of 20 kcal / mol or more does not contribute to humidification, whereas in the case of K cations in (b) Almost all of the water content contributes to humidification, and the amount is about twice that of Na cations in any SiO 2 / Al 2 O 3. In particular, Y-type zeolite having a large adsorption amount at 10 to 20 kcal / mol and having a SiO2 / Al2O3 of 2.5 to 3.0 is desirable.

  Furthermore, although the amount of desorbed water with respect to a constant heating amount of 1 kW is described here as an example, the amount of heating required to desorb the same amount of water is reduced by using zeolite of K cation with low adsorption energy. That is, there is also an energy saving effect that low temperature regeneration is possible. Chaotin is a cation ionically bonded with the molecular structure of the zeolite, and the adsorption characteristics change by ion exchange of this chaotic with various substances, so the terminal cations are exchanged according to the purpose and the adsorption characteristics. Can be improved. In addition, here, when producing the K cation zeolite as described above, it is common to use a relatively inexpensive Na cation zeolite and exchange Na ions for K ions. At this time, if the K ions are increased as much as possible, for example, if K ions: Na ions are set to 90%: 10%, the adsorption energy decreases as described above, so that the moisture desorption amount increases with respect to a certain heating amount, or is constant. There is an effect such as reduction of the heating capacity necessary for the amount of water desorption. Moreover, if the exchange amount to K ion is reduced, for example, if K ion: Na ion is about 50%: 50%, the effect of lowering the adsorption energy can be expected while reducing the cost for ion exchange.

  As described above, as an adsorbent carried on the moisture adsorption means, a porous silicon material having a large number of pores of about 1.5 to 2.5 nm, or a zeolite having a large number of pores of about 0.7 nm By using the system material, the amount of adsorption is greatly increased compared to the use of general zeolite, and the energy consumption effect of reducing the amount of heat input in the heating means necessary for generating regenerative air can be obtained. A humidifier capable of performing a humidifying operation and an air conditioner having a humidifying function can be obtained. In addition, by using a material with a mixture ratio of zeolite and silica gel that increases the mixing ratio of zeolite, it is possible to cope with a wide humidity range, and since the speed of adsorption and regeneration is improved, higher humidification capacity is secured. Further, by making the terminal cation of the zeolite a K cation having a low adsorption energy, the amount of humidification for a certain amount of heating is increased, or the heating capacity necessary for a certain amount of water desorption is reduced, that is, Low temperature regeneration is possible, and a humidifier with high humidification efficiency and an air conditioner having a humidification function can be obtained.

Embodiment 8 FIG.
FIG. 17 is a schematic installation diagram of the moisture adsorbing means according to the eighth embodiment of the present invention, wherein 54 is a moisture adsorbing means for high-humidity air, and 55 is a moisture adsorbing means for low-humidity air. Between the moisture adsorbing means 54 for high humidity air and the moisture adsorbing means 55 for low humidity air, a moisture adsorbing means partition plate 56 is installed in close contact with each other. The area 54a and area 54b, and the area 55a and area respectively. It is divided into 55b. As the adsorbent carried on the moisture adsorbing means 54 for high-humidity air, for example, the first adsorbent indicated by the isothermal adsorption line 37 in FIG. 14 includes a second adsorbent indicated by an isothermal adsorption line 38.
FIG. 18 is a conceptual diagram of the air relative humidity change at this time. 57 in (a) shows the air relative humidity change during adsorption, and 58 in (b) shows the air relative humidity change during regeneration. 59 represents the air relative humidity (Φadin) during adsorption, 60 represents the air relative humidity (Φdein) during regeneration, and Φ1, Φ2, and Φ3 represent the first relative humidity 40 and the second relative humidity shown in FIG. This corresponds to the relative humidity 41 and the third relative humidity 42.

  Next, an example of the operation will be described. The moisture adsorption means of FIGS. 1 to 3 described in the first embodiment with respect to the moisture adsorption means 54 for high humidity air, the moisture adsorption means 55 for low humidity air, and the moisture adsorption means partition plate 56 as shown in FIG. The case where the moisture adsorbing means 54 for high-humidity air is installed at the position 2 so as to be upstream of the first air blowing means 3 will be described. At this time, <A> and <B> in FIG. 17 correspond to damper positions <A> and <B> in FIG. Since the operation of the humidifying unit 1 is generally required when the room is dried during heating in winter, the outdoor air is at a low temperature (for example, 7 ° C./87% RH under the heating standard condition). At the damper position <A>, this low-temperature outside air sucked from the first intake port 16 as the adsorption inlet air 20 enters the region 6b of the first layer 6 partitioned by the first air channel partition plate 10. Since the region 14c is closed by the first air path switching damper 14, the air flows into the second layer 7 through the opening 14d. The second layer 7 is divided into semicircles by the second air passage partition plate 11, and the third layer 8 is divided into semicircles by the third air passage partition plate 12, and the water for high-humidity air sandwiched between these two layers Similarly, the moisture adsorbing means 54 and the moisture adsorbing means 55 for low-humidity air are also divided into semicircles by the moisture adsorbing means partitioning plate 56, so that the outside air flowing in from the opening 14d flows into the regions 7b, 54b, 55b, 8b. It flows downward in order, and moisture in the outside air is adsorbed when passing through the regions 54b and 55b to become dry air. Since the area 15d of the outside air that has become dry air is blocked by the second air path switching damper 15, the area 15a of the fourth layer 9 partitioned by the fourth air path partition plate 13 from the opening 15b. Then, it flows out from the first exhaust port 18 as the adsorption outlet air 22, and is exhausted to the outside through the first blowing means 3.

  On the other hand, the low-temperature outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into the region 9 b of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and rises by the heating means 5. After being heated to become high-temperature and low-humidity air, the region 15d is closed by the second air path switching damper 15, and therefore flows into the third layer 8 through the opening 15c. The third layer 8 is divided into semicircles by the third air passage partition plate 12, and the second layer 7 is divided into semicircles by the second air passage partition plate 11, and moisture for low humidity air sandwiched between the two layers. The adsorbing means 55 and the moisture adsorbing means 54 for high-humidity air are similarly divided into semicircles by the moisture adsorbing means partition plate 56. The water that flows upward in the order of 7a and adsorbed when passing through the regions 55a and 54a is regenerated to become high-humidity air. Since the area 14c is closed by the first air path switching damper 14, the outside air that has become the high humidity air is the area 6a of the first layer 6 that is partitioned by the first air path partition plate 10 from the opening 14a. And then flows out as regeneration outlet air 23 from the second exhaust port 19 and is transported into the room through the second blowing means 4 to humidify the room.

  Next, after the time for completing the adsorption process in the areas 54b and 55b and the regeneration process in the areas 54a and 55a of the moisture adsorption means 54 for high humidity air and the moisture adsorption means 55 for low humidity air has elapsed, FIG. The damper position shown in FIG. 17 is switched from <A> to <B>. At this time, the low-temperature outside air sucked from the first air inlet 16 as the adsorption inlet air 20 enters the region 6b of the first layer 6 partitioned by the first air passage partition plate 10, and the first air passage Since the region 14d is closed by the switching damper 14, it flows into the second layer 7 through the opening 14c. The second layer 7 is divided into semicircles by the second air passage partition plate 11, and the third layer 8 is divided into semicircles by the third air passage partition plate 12, and the water for high-humidity air sandwiched between these two layers Similarly, the moisture adsorbing means 54 and the moisture adsorbing means 55 for low-humidity air are also divided into semicircles by the moisture adsorbing means partition plate 56, so that the outside air flowing in from the opening 14 c flows in the regions 7 a, 54 a, 55 a, 8 a. When the regions 54a and 55a are in the damper position <A>, the moisture is regenerated and dried, so that the moisture in the outside air is adsorbed when passing through the regions 54a and 55a to become dry air. Since the area 15 c is closed by the second air path switching damper 15, the outside air that has become dry air passes from the opening 15 a to the area 9 a of the fourth layer 9 that is partitioned by the fourth air path partition plate 13. Then, it flows out from the first exhaust port 18 as the adsorption outlet air 22, and is exhausted to the outside through the first blowing means 3.

  On the other hand, the low-temperature outside air sucked from the second air inlet 17 as the regeneration inlet air 21 flows into the region 9 b of the fourth layer 9 partitioned by the fourth air passage partition plate 13 and rises by the heating means 5. After being heated to become high-temperature and low-humidity air, since the region 15c is closed by the second air path switching damper 15, it flows into the third layer 8 from the opening 15d. The third layer 8 is divided into semicircles by the third air passage partition plate 12, and the second layer 7 is divided into semicircles by the second air passage partition plate 11, and moisture for low humidity air sandwiched between the two layers. The adsorbing means 55 and the moisture adsorbing means 54 for high-humidity air are similarly divided into semicircles by the moisture adsorbing means partitioning plate 56, so that the high-temperature and low-humidity air flowing in from the opening 15d flows in the regions 8b, 55b, 54b, The water that flows upward in the order of 7b and adsorbed at the damper position <A> when passing through the regions 55b and 54b is regenerated to become high-humidity air. Since the area 14d is closed by the first air path switching damper 14, the outside air that has become the humid air is the area 6a of the first layer 6 that is partitioned by the first air path partition plate 10 from the opening 14b. And then flows out as regeneration outlet air 23 from the second exhaust port 19 and is transported into the room through the second blowing means 4 to humidify the room.

  At this time, in the areas 54b and 55b at the damper position <A> and the areas 54a and 55a at the damper position <B> that are the adsorption process, the air relative humidity change 57 at the time of adsorption shown in FIG. As shown, a large amount of moisture is adsorbed in the range of relative humidity Φadin (59) to Φ2 (41) where the amount of equilibrium adsorption of the first adsorbent carried on the moisture adsorption means 54 for high humidity air is large. For this reason, the relative humidity rapidly decreases in the thickness direction, but hardly changes when the relative humidity becomes Φ2 (41) or less. On the other hand, the equilibrium adsorption amount of the second adsorbent carried on the moisture adsorption means 55 for low-humidity air does not decrease to Φ3 (42) which is low humidity, and relative humidity Φ1 (40) to Φ3 ( 42), the moisture content of the low-humidity air having the relative humidity Φ1 (40) flowing out from the high-humidity air moisture adsorption means 54 is reduced in the relative humidity by the low-humidity air moisture adsorption means 55. Is adsorbed to the extent of φ3 (42), the amount of adsorption can be increased by q3-q1 as compared to the case of using only the moisture adsorption means 54 for high-humidity air.

  On the other hand, in the regions 55a and 54a at the damper position <A> and the regions 55b and 54b at the damper position <B> in the regeneration process, the air relative humidity change 58 at the time of regeneration shown in FIG. As shown, since the outside air as the regeneration inlet air 21 is heated by the heating unit 5, the relative humidity Φdein (60) becomes smaller than Φ3 (42) and is carried by the moisture adsorbing unit 55 for low-humidity air. In the range of relative humidity Φdein (60) to Φ3 (42) where the equilibrium adsorption amount of the second adsorbent is small, a large amount of water is regenerated, so the relative humidity increases rapidly in the thickness direction. When the relative humidity becomes Φ3 (42) or more, it hardly changes. On the other hand, the equilibrium adsorption amount of the first adsorbent carried on the moisture adsorbing means 54 for high humidity air does not rise to Φ1 (40), which is relatively high humidity, and the relative humidity Φ3 (42). To Φ1 (40) is much less than the second adsorbent, and the moisture of the low humidity air having a relative humidity of Φ3 (42) flowing out from the moisture adsorption means 55 for low humidity air is the moisture adsorption means for high humidity air. 54, since the relative humidity is regenerated to the extent of Φ2 (41), the amount of humidification corresponding to the difference in the amount of adsorption q2-q3 is reduced as compared with the case where only the moisture adsorption means 55 for low-humidity air is used. Can be increased.

  As described above, the low-humidity air moisture adsorbing means 55 carrying the second adsorbent is used for the low-humidity air adsorption in the adsorption process. Since the moisture adsorbing means 54 for high humidity air carrying the adsorbent of each other compensates each other, the pore diameter of the porous silicon material as the first adsorbent is increased as much as possible, and the first relative humidity Φ1 (40) and It is desirable to increase the second relative humidity Φ2 (41). For example, by setting the pore diameter to 2.5 nm, Φ1 (40) is 45% and Φ2 (41) is 60%, and during the regeneration shown in FIG. Since the relative humidity can be regenerated up to 60%, not only the amount of humidification is greatly increased, but also low temperature regeneration is possible, and the heating means 5 can reduce the amount of heat required for temperature increase, thereby obtaining an energy saving effect. It is done.

  In FIG. 17, the moisture adsorption means 54 for high humidity air and the moisture adsorption means 55 for low humidity air are separated, and the moisture adsorption means partition plate 56 is installed in close contact with the moisture adsorption means partition plate 56. May be installed in contact with the moisture adsorbing means 54 for high humidity air and the moisture adsorbing means 55 for low humidity air, or may be integrated and carry separate adsorbents on the front and back. In either case, there is an effect that air leakage can be completely prevented. However, when installed in contact with each other, it is necessary to align the cell positions of both honeycomb base materials so as not to cause pressure loss.

  In FIGS. 17 and 18, the adsorbent carried on the moisture adsorbing means 55 for low-humidity air has been described as the second adsorbent, but has the isothermal adsorption line 49 of FIG. 15 described in the seventh embodiment, You may use the 3rd adsorption agent which is the zeolite which made the terminal cation the K (potassium) cation with small adsorption energy. In this case, since the amount of adsorption up to the relative humidity Φ4 (50), which is a relatively high humidity, is small, if Φdein (60) is smaller than Φ4 (50) during the regeneration shown in FIG. Regeneration is possible in the minute adsorption means 55, and the amount of regeneration for a certain amount of heating can be increased, or the heating capacity necessary for a certain amount of moisture desorption can be reduced, so that the humidification efficiency can be improved.

  As described above, as the moisture adsorption means, the moisture adsorption means for high humidity carrying the first adsorbent in which the rate of change of the equilibrium adsorption amount with respect to the relative humidity changes rapidly in a relatively high humidity range, and the low humidity A low-humidity moisture adsorbing means carrying a second adsorbent that changes abruptly in series, and supplying adsorbed air from the high-humidity moisture adsorbing means side and regeneration air from the low-humidity moisture adsorbing means side Makes it possible to adsorb and regenerate within the relative humidity range suitable for each adsorbent, and to supplement each other's adsorption amount, improving the humidifying capacity compared to using one kind of adsorbent, and relatively high humidity Therefore, it is possible to increase the amount of humidification for a certain amount of heating, or to reduce the heating capacity required for a certain amount of moisture desorption, that is, to enable low-temperature regeneration. Get an air conditioner with It is possible.

The schematic block diagram of the humidification apparatus which concerns on Embodiment 1 of this invention. Detailed drawing which shows the structure of the air path which passes along the water | moisture-content adsorption | suction means of the humidification apparatus which concerns on Embodiment 1 of this invention. The top view of each air path component of FIG. 2 shown in order to demonstrate operation | movement of the humidification apparatus which concerns on Embodiment 1 of this invention. The block diagram which shows the modification of the air path switching damper in the humidification apparatus which concerns on Embodiment 1 of this invention. The detailed view which shows the structure of the air path which passes along the water | moisture-content adsorption | suction means of the humidification apparatus which concerns on Embodiment 2 of this invention. The top view of each air path component of FIG. 5 shown in order to demonstrate operation | movement of the humidification apparatus which concerns on Embodiment 2 of this invention. The top view of each air path component of FIG. 5 shown in order to demonstrate another operation | movement of the humidification apparatus which concerns on Embodiment 2 of this invention. The schematic block diagram of the humidification apparatus which concerns on Embodiment 3 of this invention. FIG. 5 is a detailed view showing a configuration of an air passage passing through a moisture adsorbing unit of a humidifying device according to Embodiment 3 of the present invention. The top view of each air path component of FIG. 9 shown in order to demonstrate operation | movement of the humidification apparatus which concerns on Embodiment 3 of this invention. The schematic block diagram of the outdoor side in the air conditioner which has a humidification function which concerns on Embodiment 4 of this invention. The schematic installation figure of the humidification apparatus in the air conditioner which has a humidification function which concerns on Embodiment 5 of this invention. The schematic installation figure of the humidification apparatus in the air conditioner which has a humidification function which concerns on Embodiment 6 of this invention. The conceptual diagram of the isothermal adsorption line of the various adsorbents (1st adsorbent, 2nd adsorbent) carry | supported by the water | moisture-content adsorption | suction means which concerns on Embodiment 7 of this invention. The conceptual diagram of the isothermal adsorption line of the adsorbent which mixed the silica gel and zeolite supported by the water | moisture-content adsorption | suction means concerning Embodiment 7 of this invention, and changed those compounding ratios. Schematic of the analysis result of the adsorption energy distribution by each terminal cation kind of the zeolite concerning Embodiment 7 of the present invention. The schematic installation figure of the water | moisture-content adsorption | suction means based on Embodiment 8 of this invention. The conceptual diagram of the air relative humidity change in the water | moisture-content adsorption | suction means which concerns on Embodiment 8 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Humidification unit, 2 Water | moisture-content adsorption | suction means, 3rd 1st ventilation means, 4th 2nd ventilation means,
DESCRIPTION OF SYMBOLS 5 Heating means, 6 1st layer, 7 2nd layer, 8 3rd layer, 9 4th layer, 10 1st air path partition plate, 11 2nd air path partition plate, 12 3rd air path partition plate , 13 4th air path partition plate, 14 1st air path switching damper (first air path switching means), 15 2nd air path switching damper (second air path switching means), 16 Inlet port, 17 Second inlet port, 18 First exhaust port, 19 Second exhaust port, 20 Adsorption inlet air, 21 Regeneration inlet air, 22 Adsorption outlet air, 23 Regeneration outlet air, 24 First 4 winds Road partition plate, 25 2nd 4 air passage partition plate, 26 outdoor unit, 27 compressor, 28 outdoor unit heat exchanger, 29 outdoor unit blower, 30 expansion valve, 31 building outer wall, 32 wall hole, 33 outdoor exhaust Mouth, 34 Indoor connection port, 35 Interior wall of building, 36 Isothermal adsorption line of general zeolite, 37 Isothermal adsorption line of first adsorbent, 3 Isothermal adsorption line of second adsorbent, 39 0th relative humidity, 40 1st relative humidity, 41 2nd relative humidity, 42 3rd relative humidity, 43 Equilibrium adsorption amount at 0th relative humidity, 44 Equilibrium adsorption amount at first relative humidity, 45 Equilibrium adsorption amount at second relative humidity, 46 Equilibrium adsorption amount at third relative humidity, 47 Isothermal adsorption line of silica gel 100%, 48 Isothermal adsorption line of zeolite 100%, 49 Isotherm adsorption line of the third adsorbent, 50 Fourth relative humidity, 51 Adsorbed moisture amount integrated value when SiO 2 / Al 2 O 3 is small, 52 Adsorbed moisture amount integrated value when in SiO 2 / Al 2 O 3, 53 SiO 2 / Al 2 O 3 Adsorbed moisture amount integral value when large, 54 Moisture adsorbing means for high-humidity air, 55 Moisture adsorbing means for low-humidity air, 56 Moisture adsorbing means partition plate, 57 Air relative humidity change during adsorption, 58 Air relative humidity change at birth, 59 Inlet air relative humidity at adsorption, 60 Inlet air relative humidity at regeneration, 70 First air path dividing means, 71 Second air path dividing means, 72 Third air path Dividing means, 73 Fourth air path dividing means.

Claims (27)

Moisture adsorption means carrying an adsorbent that adsorbs and regenerates moisture in the air, heating means for heating the air flowing into the moisture adsorption means, outside air is sucked, passes through the moisture adsorption means, and is exhausted outside the room. A humidifying device comprising a first air blowing means and a second air blowing means for sucking outside air and blowing air into the room through the heating means and the moisture adsorption means,
1st and 2nd airway division means, 2nd layer installed on one side across the moisture adsorbing means, and having an airway partition plate that divides the airway into 2 parts, and 3rd and 4th airway divisions Means,
A pair of dampers and a pair of openings provided between the first and second air passage dividing means and between the third and fourth air passage dividing means and provided diagonally. And first and second air path switching means having
The moisture adsorption means is fixedly installed in the air passage,
The humidifying apparatus according to claim 1, wherein the air passage partition plates of the second and third air passage dividing means are in close contact with the surface of the moisture adsorption means. The air passage dividers of the second and third air passage dividing means are installed in parallel,
The air passage partition plates of the first and fourth air passage dividing means are installed perpendicular to the air passage partition plates of the second and third air passage dividing means. The humidifying device according to 1.   The moisture adsorbing means has a cylindrical shape, and the dampers of the first and second air path switching means are configured such that two fan-shaped flat plates with a central angle of 90 ° are connected diagonally at the center. The humidifying device according to claim 1, wherein the humidifying device is installed diagonally at an angle different by 90 °. Of the two air passages divided by the air passage partition plate of the first air passage dividing means, a first air inlet for sucking outside air into one air passage side communicating with the first air blowing means, the second An indoor connection port for ventilating indoors is provided on the other air passage side communicating with the air blowing means,
Of the two air passages divided by the air passage partition plate of the fourth air passage dividing means, the second air inlet for sucking the heating means and the outside air into one air passage side communicating with the second air blowing means And providing an exhaust port for exhausting to the outside on the other air passage side communicating with the first air blowing means,
The first air blowing means sucks outside air from the first air intake port, passes through the moisture adsorbing means, and exhausts the air from the exhaust port to the outside of the room. The direction of the air flow that sucks outside air from the second air inlet, passes through the heating means and the moisture adsorbing means, and flows into the room from the indoor connection port is reversed when passing through the moisture adsorbing means. The humidifier according to any one of claims 1 to 3.   5. The air path switching is performed by rotating the first and second air path switching means in the same direction or in the forward and reverse directions at a rotation angle of 90 [deg.]. A humidifier according to any one of the above.   The dampers of the first and second air path switching means are arranged on the entire radial portions at both ends of the fan-shaped flat plate, or the air path partition plates of the first and third air path dividing means or the second and fourth air paths. Protrusions that abut against the airway partition plate of the road dividing means, and the airway switching is performed by the first and second airway switching means interlocking and repeating 90 ° forward and reverse rotation. The humidifier according to any one of claims 1 to 4.   The first intake port spans one opening of the first air path switching means and one area divided by the air path partition plates of the first and second air path dividing means. The indoor connection port is located in the other opening divided by the other opening of the first air passage switching means and by the air passage dividers of the first and second air passage dividing means. The second air inlet is divided into one opening of the second air path switching means and by the air path partition plate of the third and fourth air path dividing means. The exhaust port is divided into the other opening of the second air passage switching means and by the air passage dividers of the third and fourth air passage dividing means. The humidifying device according to claim 4, wherein the humidifying device is installed across the other region.   The first and second air path switching means, the first intake port, the indoor connection port, the second intake port, and the exhaust port are rotated by 90 ° in the same direction in conjunction with each other. 8. A humidifier according to claim 7, wherein the path is switched.   The dampers of the first and second air path switching means are the air path partition plates of the first and second air path dividing means and the air path partition plates of the third and fourth air path dividing means, respectively. And the first intake port, the indoor connection port, the second intake port, and the exhaust port are rotated by 180 ° in conjunction with each other to switch the air path. The humidifier according to claim 7.   The moisture adsorbing means has a rectangular parallelepiped shape, and the dampers of the first and second air path switching means have two L-shaped plates diagonally connected at the corners of the L shape, and The humidifying device according to any one of claims 1 to 6, wherein the humidifying device is installed in diagonal directions different by 90 °.   The damper of the said 1st and 2nd air path switching means was comprised integrally so that the air path partition plate of the said 2nd and 3rd air path division | segmentation means might be formed, respectively. The humidifier described. Moisture adsorption means carrying an adsorbent that adsorbs and regenerates moisture in the air, heating means for heating the air flowing into the moisture adsorption means, outside air is sucked, passes through the moisture adsorption means, and is exhausted outside the room. A humidifying device comprising a first air blowing means and a second air blowing means for sucking outside air and blowing air into the room through the heating means and the moisture adsorption means,
1st and 2nd airway division means, 2nd layer installed on one side across the moisture adsorbing means, and having an airway partition plate that divides the airway into 2 parts, and 3rd and 4th airway divisions Means,
A pair of dampers and a pair of openings provided between the first and second air passage dividing means and between the third and fourth air passage dividing means and provided diagonally. And first and second air path switching means having
The moisture adsorption means is fixedly installed in the air passage,
The air passage partition plates of the second and third air passage dividing means are in close contact with the surface of the water adsorption means. The water adsorption means has a rectangular parallelepiped shape, and the first and second air path switching. The humidifier is characterized in that the damper of the means has two L-shaped plates connected diagonally at the corners of the L-shape, and is installed in a diagonal direction different by 90 °.   13. The dampers of the first and second air path switching means are integrally configured so as to form air path partition plates of the second and third air path dividing means, respectively. The humidifier described.   The adsorbent supported by the moisture adsorbing means is composed of a silicon material provided with a large number of pores having a pore diameter of 1.5 to 2.5 nanometers, and the first relative humidity which is low humidity and the first The rate of change of the equilibrium adsorption amount of water relative to the relative humidity in the range relative to the second relative humidity, which is higher than the relative humidity, is greater than the rate of change of the equilibrium adsorption amount relative to the relative humidity outside the range of the relative humidity. The first adsorbent which is large and has an adsorption characteristic such that the first relative humidity and the second relative humidity are in the range of 30% to 60% is used. The humidifying device according to any one of 13.   The adsorbent supported by the moisture adsorbing means is composed of a zeolite-based material provided with a large number of pores having a pore diameter of 0.7 nanometer, and has a lower humidity than the first relative humidity. A second adsorption characteristic in which the rate of change of the equilibrium adsorption amount of water relative to the relative humidity in the range below the relative humidity is greater than the rate of change of the equilibrium adsorption amount relative to the relative humidity in the range above the third relative humidity; The humidifier according to claim 1, wherein an adsorbent is used.   The adsorbent supported on the moisture adsorbing means is a mixture of zeolite and silica gel, which is synthesized by increasing the blending ratio of zeolite, and the terminal cation species of the zeolite is 50% or more of potassium. The humidifying device according to claim 1, wherein a third adsorbent having a ratio is used.   As the moisture adsorbing means, a first moisture adsorbing means and a second moisture adsorbing means carrying different adsorbents are arranged in series, and the first moisture is disposed upstream of the first air blowing means. The humidifying device according to any one of claims 1 to 13, wherein a suction means is arranged.   The humidifying device according to claim 17, wherein the first adsorbent is used as an adsorbent carried on the first moisture adsorbing means.   The humidifying device according to claim 17, wherein the second adsorbent is used as an adsorbent carried on the second moisture adsorbing means.   18. The humidifying device according to claim 17, wherein the third adsorbent is used as an adsorbent carried on the second moisture adsorbing means. A heat pump cycle including a compressor, an indoor heat exchanger, an outdoor heat exchanger, and an expansion valve, the outdoor unit including the compressor, the outdoor heat exchanger, and the expansion valve; and the indoor heat In an air conditioner that connects an indoor unit with a built-in exchanger with a refrigerant pipe,
An air conditioner having a humidifying function, wherein the humidifying device according to any one of claims 1 to 20 is installed integrally with the outdoor unit. A heat pump cycle including a compressor, an indoor heat exchanger, an outdoor heat exchanger, and an expansion valve, the outdoor unit including the compressor, the outdoor heat exchanger, and the expansion valve; and the indoor heat In an air conditioner that connects an indoor unit with a built-in exchanger with a refrigerant pipe,
The room for installing the humidification device according to any one of claims 1 to 20 in the outdoor part near the wall hole which penetrates the refrigerant piping, and ventilating into the room by the 2nd ventilation means of the humidification device An air conditioner having a humidifying function, wherein the connection port faces the wall hole. A heat pump cycle including a compressor, an indoor heat exchanger, an outdoor heat exchanger, and an expansion valve, the outdoor unit including the compressor, the outdoor heat exchanger, and the expansion valve; and the indoor heat In an air conditioner that connects an indoor unit with a built-in exchanger with a refrigerant pipe,
The humidifying device according to any one of claims 1 to 20, wherein the humidifying device is installed on the indoor side in the vicinity of a wall hole that penetrates the refrigerant pipe, and the first blowing unit and the second blowing unit of the humidifying device are An air conditioner having a humidifying function, characterized in that indoor air is sucked and an exhaust port for exhausting the air to the outside by the first blower means faces the wall hole.   The adsorbent supported by the moisture adsorbing means is composed of a silicon material provided with a large number of pores having a pore diameter of 1.5 to 2.5 nanometers, and the first relative humidity which is low humidity and the first The rate of change of the equilibrium adsorption amount of water relative to the relative humidity in the range relative to the second relative humidity, which is higher than the relative humidity, is greater than the rate of change of the equilibrium adsorption amount relative to the relative humidity outside the range of the relative humidity. The first adsorbent which is large and has an adsorption characteristic such that the first relative humidity and the second relative humidity are in the range of 30% to 60% is used. The air conditioner which has a humidification function in any one of 23.   The adsorbent supported by the moisture adsorbing means is composed of a zeolite-based material provided with a large number of pores having a pore diameter of 0.7 nanometer, and has a lower humidity than the first relative humidity. A second adsorption characteristic in which the rate of change of the equilibrium adsorption amount of water relative to the relative humidity in the range below the relative humidity is greater than the rate of change of the equilibrium adsorption amount relative to the relative humidity in the range above the third relative humidity; The air conditioner having a humidifying function according to any one of claims 21 to 23, wherein an adsorbent is used.   The adsorbent supported on the moisture adsorbing means is a mixture of zeolite and silica gel, which is synthesized by increasing the blending ratio of zeolite, and the terminal cation species of the zeolite is 50% or more of potassium. The air conditioner having a humidifying function according to any one of claims 21 to 23, wherein a third adsorbent having a ratio is used.   As the moisture adsorbing means, a first moisture adsorbing means and a second moisture adsorbing means carrying different adsorbents are arranged in series, and the first moisture is disposed upstream of the first air blowing means. The air conditioner having a humidifying function according to any one of claims 21 to 23, wherein an adsorbing means is disposed.

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