JP2006275486A - Humidity adjustment device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidity adjustment device for avoiding an increase in the sliding resistance with the thermal expansion of an adsorption rotor while eliminating the need for the rotating shaft of the adsorbing rotor. <P>SOLUTION: On the outer periphery of the adsorption rotor 50, a frame body 60 is provided for holding the adsorption rotor 50. On the frame body 60, a guide portion 63 is provided on the lower side which has an inner peripheral face in slide contact with the half or less of the outer periphery of the adsorption rotor 50 and a large diameter portion 64 is provided on the upper side which has a larger curvature radius than the inner peripheral face of the guide portion 63. The adsorption rotor 50 is guided in the peripheral direction by the guide portion 63 and rotated in slide contact with the guide portion 63. When thermally expanded, the adsorption rotor 50 is displaced toward the large diameter portion 64 while being kept in slide contact with the guide portion 63. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a humidity control apparatus including an adsorption rotor that rotates while straddling two air passages.

  Conventionally, a humidity control apparatus that performs dehumidification and humidification of air by an adsorption rotor is known.

  For example, in the humidity control device disclosed in Patent Document 1, first and second passages through which air flows are formed in the casing. An adsorption rotor is arranged in the casing so as to straddle the first passage and the second passage. The adsorption rotor is configured such that an adsorbent such as silica gel, zeolite, or alumina is supported on a disk-like base material in which a plurality of vent holes are formed. The suction rotor has a shaft center supported by a rotating shaft, and is driven to rotate about the rotating shaft by a driving source such as a motor. In the humidity control apparatus, a heating coil is disposed on the upstream side of the adsorption rotor in the second passage.

  During the dehumidifying operation of the humidity control apparatus, the air sucked from the room and flowing through the first passage passes through the adsorption zone of the adsorption rotor. As a result, moisture in the air is adsorbed by the adsorbent and the air is dehumidified. The air dehumidified as described above is supplied indoors. On the other hand, the air sucked from the room and flowing through the second passage is heated by the heating coil and then passes through the regeneration zone of the adsorption rotor. As a result, moisture adsorbed by the adsorption rotor is desorbed and released into the air, and the adsorption rotor is heated and regenerated. As described above, the air used for regenerating the adsorption rotor is discharged to the outside.

  By the way, the humidity control apparatus disclosed in Patent Document 1 is configured to rotate the suction rotor about the rotation shaft. For this reason, the bearing surface of the suction rotor may be worn out or deteriorated due to the sliding contact between the rotation shaft and the bearing surface of the suction rotor, which may make it difficult to stably rotate the suction rotor. .

As a conventional technique for solving such a problem, for example, an adsorption rotor disclosed in Patent Document 2 can be cited. This adsorption rotor is not provided with a rotation shaft at its axis, and is provided with a frame on the outer peripheral side thereof. The frame is formed with a circular mouth extending over the entire outer periphery of the suction rotor, and the suction rotor is rotatably held in the circular mouth. A geared motor is housed inside the frame. A drive belt is stretched between the geared motor and the outer peripheral surface of the suction rotor. When the geared motor is operated, the rotational force of the geared motor is transmitted to the adsorption rotor via the drive belt. As a result, the suction rotor is driven to rotate inside the frame while being guided by the inner peripheral surface of the frame. As described above, since the rotation shaft is unnecessary in the suction rotor of Patent Document 2, it is possible to reliably prevent wear and deterioration of the shaft center of the suction rotor.
JP 2001-263727 A JP 2003-10626 A

  However, when the suction rotor disclosed in Patent Document 2 is applied to the humidity control apparatus disclosed in Patent Document 1, the following problems occur. That is, at the time of regeneration of the adsorption rotor, it is necessary to pass heated air through the adsorption rotor, so that the base material of the adsorption rotor is thermally expanded. Therefore, the sliding resistance between the outer peripheral surface of the suction rotor and the inner peripheral surface of the frame body is increased, which may increase the rotational power of the suction rotor.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a humidity control apparatus that eliminates the need for the rotation shaft of the adsorption rotor and avoids an increase in sliding resistance due to thermal expansion of the adsorption rotor. There is to do.

  The first invention includes a casing (10) having first and second passages (41, 42) through which air flows, and an adsorption rotor (50) that rotates while straddling both passages (41, 42), It is premised on a humidity control device that adsorbs moisture in the air flowing through the first passage (41) by the adsorption rotor (50) and heats and regenerates the adsorption rotor (50) with the air flowing through the second passage (42). And this humidity control apparatus is provided with the guide part (63) which slidably contacts with the half or less part of the circumferential direction among the outer peripheral surfaces of an adsorption | suction rotor (50), and guides this adsorption | suction rotor (50) to the circumferential direction. Is.

  In the first invention, the adsorption rotor (50) rotates while straddling the first passage (41) and the second passage (42). When the air flowing through the first passage (41) passes through the adsorption rotor (50), moisture in the air is adsorbed by the adsorbent of the adsorption rotor (50). As a result, the air flowing through the first passage (41) is dehumidified. On the other hand, the air flowing through the second passage (42) is heated by, for example, a heat exchanger or a heater, and then passes through the adsorption rotor (50). In the adsorption rotor (50), water adsorbed by the adsorbent is released into the air, and the adsorption rotor (50) is heated and regenerated. As described above, suction and regeneration are alternately performed at each portion of the suction rotor (50). As a result, in this humidity control apparatus, dehumidification and humidification of air are continuously performed.

  Here, in this invention, a guide part (63) is provided in the outer peripheral side of an adsorption | suction rotor (50). The guide part (63) is in sliding contact with the outer peripheral surface of the suction rotor (50) and guides the suction rotor (50) in the circumferential direction. For this reason, it becomes possible to rotate the adsorption rotor (50) along the guide portion (63) without providing a rotation shaft at the axis of the adsorption rotor (50).

  Further, the guide portion (63) is configured to be in sliding contact with a portion of the outer peripheral surface of the suction rotor (50) that is half or less in the circumferential direction. In other words, more than half of the outer peripheral surface of the suction rotor (50) is not in sliding contact with the guide portion (63). For this reason, even if the adsorption rotor (50) is heated by the air flowing through the second passage (42) and is thermally expanded, the adsorption rotor (50) is kept in sliding contact with the guide portion (63) while the guide portion (63 ) To the opposite side. That is, an escape space for the thermally expanding adsorption rotor (50) is formed on the outer periphery of the adsorption rotor (50). Therefore, it is possible to avoid an increase in sliding resistance between the suction rotor (50) and the guide portion (63) during the thermal expansion of the suction rotor (50).

  In a second aspect based on the first aspect, the suction rotor (50) is disposed in a posture in which the axis of the suction rotor (50) is in a horizontal direction and an oblique direction, and the guide portion (63) is It is at least slidably in contact with the lower outer peripheral surface of the suction rotor (50).

  In the second invention, the suction rotor (50) is arranged in the casing (10) in such a posture that its end surface is a vertical surface or an inclined surface. On the other hand, the guide portion (63) is provided on the lower side of the suction rotor (50) so as to be in sliding contact with the lower outer peripheral surface of the suction rotor (50). As a result, the suction rotor (50) is supported by the guide portion (63), and the suction rotor (50) can be stably rotated without a rotation shaft.

  A third invention includes an annular frame (60) surrounding the outer periphery of the adsorption rotor (50), and the frame (60) has an inner circumferential surface as an arc surface, and the adsorption rotor (50) A gap (65) is formed between the small-diameter portion that is in sliding contact with the outer peripheral surface and the inner peripheral surface is an arc surface having a larger radius of curvature than the inner peripheral surface of the small-diameter portion, and the outer periphery of the suction rotor (50). The large-diameter portion (64) and the small-diameter portion of the frame (60) constitute a guide portion (63).

  In 3rd invention, a frame (60) is provided in the outer periphery of an adsorption | suction rotor (50). The inner peripheral surface of the frame (60) is constituted by an inner peripheral surface of the guide portion (63) serving as a small diameter portion and an inner peripheral surface of the large diameter portion (64). Therefore, in a state where the adsorption rotor (50) is not thermally expanded, the lower outer peripheral surface of the adsorption rotor (50) is in sliding contact with the guide portion (63), while the upper outer peripheral surface of the adsorption rotor (50) is The gap (65) is formed between the large diameter portion (64). Therefore, when the suction rotor (50) is thermally expanded, the suction rotor (50) keeps the sliding portion (63) in sliding contact with the guide portion (63) on the lower side of the outer peripheral surface, while the clearance (65) is escaped upward. Displace.

  According to a fourth invention, in the third invention, the frame (60) is formed with a fluororesin film at a sliding contact portion with the adsorption rotor (50).

  In the fourth invention, the fluororesin film is formed on the frame (60) at least in the sliding contact portion with the adsorption rotor (50). As a result, the sliding resistance between the suction rotor (50) and the frame (60) is reduced.

  In a fifth aspect based on the second aspect, the suction rotor (50) has a plurality of teeth formed on the outer peripheral side thereof, and meshes with teeth on the lower outer peripheral surface of the suction rotor (50). A drive gear (70) for rotating the suction rotor (50) is provided.

  In the fifth invention, a plurality of teeth are formed on the outer periphery of the suction rotor (50), and a drive gear (70) that meshes with the teeth of the suction rotor (50) is provided. Therefore, the suction rotor (50) can be rotationally driven by the drive gear (70). Here, the drive gear (70) is disposed on the lower side of the suction rotor (50) so as to mesh with the teeth on the lower outer peripheral surface of the suction rotor (50). Accordingly, the weight of the suction rotor (50) acts on the drive gear (70), and the meshing of the teeth of the suction rotor (50) and the teeth of the drive gear (70) is stabilized.

  According to a sixth invention, in the fifth invention, the guide portion (63) is formed at least on the substantially opposite side of the drive gear (70) with the suction rotor (50) interposed therebetween. Is.

  In the sixth invention, the guide portion (63) is formed at a position facing the drive gear (70) on the outer periphery of the suction rotor (50). For this reason, when the suction rotor (50) is driven to rotate, even if a force directed from the drive gear (70) in the axial direction of the suction rotor (50) acts on the suction rotor (50), it faces the drive gear (70). The guide portion (63) at the position to be used serves as a stopper and holds the suction rotor (50). Therefore, the meshing between the drive gear (70) and the suction rotor (50) is further stabilized.

  The seventh invention includes a casing (10) having first and second passages (41, 42) through which air flows, and an adsorption rotor (50) that rotates while straddling both passages (41, 42), It is premised on a humidity control device that adsorbs moisture in the air flowing through the first passage (41) by the adsorption rotor (50) and heats and regenerates the adsorption rotor (50) with the air flowing through the second passage (42). And this humidity control apparatus is provided with the guide part (63) which slidably contacts with a part of outer peripheral surface of the said adsorption | suction rotor (50), and guides this adsorption | suction rotor (50) to the circumferential direction, The said guidance part (63) Is characterized in that it is in a non-contact state with a portion of the outer peripheral surface of the suction rotor (50) that extends over half of the circumferential direction.

  In 7th invention, a guide part (63) is provided in the outer peripheral side of an adsorption | suction rotor (50). The guide portion (63) is in a non-contact state with a portion extending over half of the outer peripheral surface of the adsorption rotor (50), and conversely, is configured to be in sliding contact with less than half of the outer peripheral surface of the adsorption rotor (50). ing. For this reason, even if the suction rotor (50) is thermally expanded, the suction rotor (50) remains in the state of being guided by the guide portion (63), and the non-contact portion is opposite to the guide portion (63). Displace to the side. Therefore, it is possible to avoid an increase in sliding resistance between the suction rotor (50) and the guide portion (63) during thermal expansion of the suction rotor (50).

  In the present invention, a guide portion (63) that slides in contact with the suction rotor (50) and guides the suction rotor (50) in the circumferential direction is provided. For this reason, it becomes possible to rotate the adsorption rotor (50) without providing a rotation shaft at the axis of the adsorption rotor (50).

  In the present invention, when the adsorption rotor (50) is thermally expanded, the adsorption rotor (50) is displaced toward the escape space. For this reason, an increase in sliding resistance between the suction rotor (50) and the guide portion (63) can be avoided.

  In this way, the rotational power of the suction rotor (50) can be reduced, and the drive source such as a motor can be made compact. Moreover, the running cost of this humidity control apparatus can be reduced. Moreover, the adsorption rotor (50) can be rotated stably, and the reliability of this humidity control apparatus can be improved. Furthermore, the wear and deterioration of the outer peripheral surface of the adsorption rotor (50) can be suppressed, and the life of the adsorption rotor (50) can be extended.

  In the second aspect of the present invention, the suction rotor (50) is arranged in such a posture that the end surface is a vertical surface or an inclined surface, and the guide portion (63) is arranged on the lower side thereof. As a result, the suction rotor (50) can be reliably supported by the guide portion (63), and the suction rotor (50) can be rotated stably.

  According to the third aspect of the present invention, the suction rotor (50) can be held inside the frame (60) by fitting the suction rotor (50) inside the annular frame (60). . Therefore, the adsorption rotor (50) can be stably rotated without providing a rotation shaft. Here, since the large-diameter portion (64) is provided on the inner peripheral surface of the frame (60), there is a relief space between the outer peripheral surface of the suction rotor (50) and the large-diameter portion (64). A gap (65) can be formed. Therefore, it is possible to avoid an increase in sliding resistance between the suction rotor (50) and the inner peripheral surface of the frame (60) during the thermal expansion of the suction rotor (50).

  According to the fourth aspect of the present invention, the fluororesin film is formed on the sliding contact portion between the frame (60) and the suction rotor (50), so that the sliding contact between the frame (60) and the suction rotor (50) is achieved. The sliding resistance of the part can be reduced. Therefore, the power of the suction rotor (50) can be effectively reduced, and the drive source of the suction rotor (50) can be made more compact.

  According to the fifth aspect, the suction rotor (50) can be provided without rotating shafts by rotating the drive gear (70) while guiding the suction rotor (50) in the circumferential direction by the guide portion (63). Can be rotated stably. Further, since the drive gear (70) is disposed on the lower side of the outer peripheral surface of the adsorption rotor (50), the engagement between the drive gear (70) and the adsorption rotor (50) is stable. Therefore, the adsorption rotor (50) can be rotated more stably.

  According to the sixth aspect of the invention, the guide portion (63) is provided on the opposite side of the drive gear (70) with the suction rotor (50) interposed therebetween. For this reason, the meshing between the drive gear (70) and the suction rotor (50) is stable, and the suction rotor (50) can be rotated more stably. Further, when the suction rotor (50) rotates, the suction rotor (50) can be reliably held by the guide portion.

  In the seventh aspect of the invention, during the thermal expansion of the suction rotor (50), the suction rotor (50) is connected to the guide portion (63) while maintaining the sliding contact between the guide portion (63) and the suction rotor (50). It is made to displace to the non-contact part side. For this reason, an increase in sliding resistance between the suction rotor (50) and the guide portion (63) can be suppressed, and the same effect as in the first invention can be achieved.

  The humidity control apparatus of the present embodiment is mounted on a desk-type small air conditioner (1) installed on a desk such as an office. The air conditioner (1) is a so-called spot cooler type air conditioner that supplies cold air toward an office worker.

<Overall configuration>
First, the whole structure of this air conditioner (1) is demonstrated, referring FIGS. 1-3. 1 is a perspective view of the air conditioner (1) as viewed from the front, FIG. 2 is a perspective view of the air conditioner (1) as viewed from the rear, and FIG. 3 is a view of the inside of the air conditioner (1) as viewed from the right side. It is.

  The air conditioner (1) includes a flat box-shaped casing (10) at the front and rear. The casing (10) consists of a front panel (11) on the front side, a rear panel (12) on the rear side, a top plate (13) on the upper side, a bottom plate (14) on the lower side, a right side plate (15) on the right side, and a left side Left side plate (16). The casing (10) is formed with an air outlet (21), a front suction port (22), a rear suction port (23), and an exhaust port (24).

  The said blower outlet (21) is formed in the upper end part of a front panel (11). The air outlet (21) is formed to extend in the horizontal direction from the right end to the left end of the front panel (11). A flap (25) is housed inside the air outlet (21). The flap (25) is configured to be rotatable in a predetermined vertical range with a horizontal axis (not shown) provided at the left and right ends thereof as a fulcrum. Furthermore, in the flap (25), a plurality of vertical blades (26) formed in a plate shape extending in the front-rear direction are arranged in the left-right direction. Each vertical blade (26) is configured to be rotatable in a predetermined range of right and left with a vertical shaft (not shown) provided at the upper and lower ends thereof as a fulcrum. As described above, the flap (25) can switch the wind direction of the cold air blown into the room from the air outlet (21) up, down, left and right.

  The front suction port (22) is formed near the lower center of the front panel (11). The rear suction port (23) is formed at a position near the right side plate (15) at the lower part of the rear panel (12). The exhaust port (24) is formed at a position near the left side plate (16) at the rear of the top plate (13).

  On the left side inside the casing (10), a left partition plate (30) is provided. The left partition plate (30) has a front end connected to the front panel (11), and is formed to extend forward and backward from the front panel (11) toward the rear panel (12). The left partition plate (30) is formed in an inverted L shape in which the lower half of the rear part is cut. And as for the rear part of the left part partition plate (30), the upper half is connected to the rear panel (12), while the lower half is located in the front-rear center in the casing (10).

  The casing (10) is provided with first to fourth partition plates (31, 32, 33, 34) across the left partition plate (30) and the right plate (15). ing.

  The first partition plate (31) is formed to extend obliquely from the front end portion of the bottom plate (14) to the rear end portion of the top plate (13). That is, the first partition plate (31) divides the space between the left partition plate (30) and the right side plate (15) into a space extending upward on the front side and a space expanding downward on the rear side.

  The first partition plate (31) has a circular opening, and the frame (60) is connected to the opening. Further, the frame (60) has a circular opening, and the suction rotor (50) is held inside the circular opening. (Details of the suction rotor and the frame will be described later).

  The second partition plate (32) partitions the space extending above the front side of the first partition plate (31) into two upper and lower spaces. Of these two spaces, the upper space constitutes the outlet passage (43), and the lower space constitutes the suction passage (44). Further, a front side plate member (71), which will be described in detail later, is connected to the rear end portion of the second partition plate (32). The front plate member (71) is formed to extend in the horizontal direction from the left partition plate (30) to the right plate (15).

  The outlet passage (43) communicates with the outlet (21). A first heat exchanger (36) is accommodated in the outlet passage (43). The first heat exchanger (36) is disposed in the vicinity of the air outlet (21) in a posture inclined obliquely along the first partition plate (31). The first heat exchanger (36) is a plate fin heat exchanger.

  The suction passage (44) communicates with the front suction port (22). A second heat exchanger (37) is accommodated in the suction passage (44). The second heat exchanger (37) is arranged in the vicinity of the front suction port (22) in a posture in which the second heat exchanger (37) is erected vertically along the front panel (11). The second heat exchanger (37) is a plate fin heat exchanger.

  The third partition plate (33) partitions the space extending downward and rearward of the first partition plate (31) into two upper and lower spaces. Of these two spaces, the upper space constitutes the upper passage (45). On the other hand, a fourth partition plate (34) extending vertically from the front end of the third partition plate (33) to the bottom plate (14) is formed in the lower space. The fourth partition plate (34) partitions the lower space of the third partition plate (33) into a lower passage (46) and a storage chamber (47). In addition, a rear plate member (72), which will be described in detail later, is connected to the front end portion of the third partition plate (33). The rear side plate member (72) is formed to extend in the horizontal direction from the left partition plate (30) to the right side plate (15) in the same manner as the front side plate member (71).

  The upper passage (45) is formed between the first partition plate (31) and the third partition plate (33). The upper passage (45) communicates with the blowing passage (43) through a plurality of air holes formed in the adsorption rotor (50). The lower passage (46) is formed between the first partition plate (31) and the fourth partition plate (34). The lower passage (46) communicates with the suction passage (44) through a plurality of ventilation holes formed in the adsorption rotor (50).

  The storage chamber (47) includes a space between the third partition plate (33) and the fourth partition plate (34), and a space between the left partition plate (30) and the left side plate (16). Connected and configured. The storage chamber (47) communicates with the exhaust port (24). A first fan (38), a second fan (39), and a compressor (40) are housed in the rear side of the storage chamber (47) in order from the right side to the left side.

  The first fan (38) is installed in the storage chamber (47) via a pedestal (not shown). The suction port of the first fan (38) is connected to the rear suction port (23). On the other hand, the discharge duct of the first fan (38) extends upward and passes through the third partition plate (33), and the discharge port of the first fan (38) faces the upper passage (45). Therefore, the rear suction port (23) does not communicate with the storage chamber (47) but communicates with the upper passage (45) via the first fan (38).

  The second fan (39) is installed on the bottom plate (14). The suction port of the second fan (39) is connected to the communication port (48) formed in the fourth partition plate (34) (see FIG. 3). On the other hand, the discharge duct of the second fan (39) faces the storage chamber (47). Accordingly, the lower passage (46) communicates with the exhaust port (24) via the second fan (39) and the storage chamber (47).

  The compressor (40) is a positive displacement fluid machine such as a rotary compressor. A refrigerant pipe having an expansion valve is connected to the discharge pipe and the suction pipe of the compressor (40) (not shown). The refrigerant pipe extends forward through the space on the left side of the storage chamber (47) and then passes through the left partition plate (30) to connect to the first and second heat exchangers (36, 37). Yes. The compressor (40), the first and second heat exchangers (36, 37), and the expansion valve are connected by a refrigerant pipe, thereby constituting a refrigerant circuit that circulates refrigerant and performs a refrigeration cycle. Has been.

  As described above, the first and second passages (41, 42) through which air flows are formed in the casing (10). The first passage (41) is configured by connecting a rear suction port (23), an upper passage (45), an outlet passage (43), and an outlet (21) in order from the upstream side of the air. On the other hand, in the second passage (42), the front suction port (22), the suction passage (44), the lower passage (46), the storage chamber (47), and the exhaust port (24) are connected in order from the upstream side of the air. Has been configured.

<Configuration of suction rotor and frame>
Next, the configuration of the suction rotor (50) and the frame (60) described above will be described with reference to FIGS. 4 is an exploded perspective view of the state in which the suction rotor (50) is removed from the frame (60), and FIG. 5 is a front and rear view of the frame (60) with the suction rotor (50) attached. FIG. 6 is a schematic configuration view of the suction rotor (50) viewed from the front side (in FIG. 6, illustration of a net member described later is omitted).

  The suction rotor (50) and the frame (60) are installed in the casing (10) in such a manner that the front and rear side surfaces are inclined about 30 degrees rearward from the vertical direction. That is, the axis of the suction rotor (50) is directed in an oblique direction between the vertical direction and the horizontal direction. The suction rotor (50) is held between the pair of plate members (71, 72) described above while being held inside the frame (60). These plate members (71, 72) are connected to each other by a pair of connecting members (73, 73) that connect the left and right end portions respectively. The adsorption rotor (50) is configured to be rotatable inside the frame (60) while straddling the first passage (41) and the second passage (42).

  As shown in FIGS. 4 and 5, the suction rotor (50) is configured by integrally fixing a base material (51), a pair of net members (52, 53), and an annular member (57). Yes.

  The base material (51) has an outer edge formed in a disk shape. On the other hand, the inside of the base material (51) is formed in a honeycomb shape, and a plurality of vent holes penetrating in the front-rear direction are formed. This base material (51) carries silica gel, zeolite, alumina or the like as an adsorbent for adsorbing moisture in the air.

  The mesh member includes a first mesh member (52) adhered to the front surface of the base material (51) and a second mesh member (53) adhered to the rear surface. Both mesh members (52, 53) are each made of a resin material formed in a disk shape. Each mesh member (52, 53) includes an annular ring member (54) located on the outer periphery and a plurality of ribs extending radially from the axis of the mesh member (52, 53) over the ring member (54). (55). Each net member (52, 53) includes an annular reinforcing member (56) at a radial intermediate position between the shaft center and the ring member (54). Each mesh member (52, 53) has a plurality of openings (58) through which air can flow between the ring member (54), the reinforcing member (56), and the plurality of ribs (55). ing.

  Moreover, as shown in FIG. 5, the outer diameter of the 1st net member (52) is comprised larger than the outer diameter of the said base material (51) and the 2nd net member (53). Further, on the outer peripheral surface of the second mesh member (53), annular notches (59a, 59b) are formed at the front end portion and the rear end portion, respectively.

  The annular member (57) is bonded to the outer peripheral surface of the substrate (51). Although not shown, a plurality of teeth are formed on the outer peripheral surface of the annular member (57). These teeth of the annular member (57) mesh with teeth of a drive gear (70) described later. The rear part of the annular member (57) is thinner than the front part. Further, the rear end of the annular member (57) is bent radially inward so as to cover the entire outer peripheral end of the rear surface of the base member (51). The second mesh member (53) described above is bonded to the annular member (57) and the base material (51) so that the bent portion of the annular member (57) is fitted into the notch (59a) on the front side. .

  The frame (60) includes a plate part (61) connected to the first partition plate (31) and an annular holding part (62) protruding forward from the plate part (61).

  As shown in FIG. 5, the plate portion (61) is formed in a plate shape with short front and rear thicknesses, and a circular mouth is formed therein. The plate portion (61) is composed of an inner plate portion (61a) located on the inner peripheral side of the holding portion (62) and an outer plate portion (61b) located on the outer peripheral side of the holding portion (62). Has been. The outer plate portion (61b) is connected to the first partition plate (31) described above.

  The holding part (62) has an inner diameter slightly larger than the circular opening of the plate part (61). The suction rotor (50) has a notch (59b) on the rear side of the second mesh member (53) fitted into a circular opening of the plate portion (61) and a rear end of the annular member (57). And the outer peripheral surface of the second net member (53) are held by the frame (60) so that they are positioned inside the holding portion (62).

  Further, as shown in FIG. 6, a drive gear (70) is provided on the front surface of the plate portion (61) in the vicinity of the outer peripheral surface slightly closer to the lower side of the suction rotor (50). Specifically, the suction rotor (50) is disposed at a position of about 100 degrees in the clockwise direction on the outer periphery of the suction rotor (50) with respect to the upper end thereof. The drive gear (70) meshes with a plurality of teeth formed on the annular member (57), and rotates the suction rotor (50) by the rotation of the motor.

  On the inner peripheral surface of the holding portion (62), an arc-shaped cutout groove (65) is formed on the upper side. That is, the holding portion (62) has a guide portion (63) that is a small-diameter portion that is in sliding contact with the outer peripheral surface of the suction rotor (50), and is formed on the lower side of the suction rotor (50). A large diameter part (64) having an inner peripheral surface larger than the radius of curvature of the inner peripheral surface is formed closer to the upper side of the suction rotor (50). And the clearance gap is formed by the said notch groove (65) between the outer peripheral surface of the adsorption | suction rotor (50), and the holding | maintenance part (62).

  Specifically, the guide part (63) is formed over a range of a circumferential angle of about 150 degrees. One circumferential end of the guide portion (63) is positioned at approximately 135 degrees in the clockwise direction with respect to the upper end of the suction rotor (50), and the other peripheral end is based on the upper end of the suction rotor (50). It is located at about 285 degrees clockwise in the circumferential direction. On the other hand, the said large diameter part (64) is formed ranging over the range of the circumferential angle of about 210 degree | times so that it may straddle the both peripheral ends of the said guide part (63).

  The frame (60) is formed with a fluororesin coating at the sliding portion with the suction rotor (50). Specifically, the fluororesin coating is formed on the sliding surface between the inner peripheral surface of the holding portion (62) and the second mesh member (53) of the inner plate portion (61a) in the frame (60). Is formed.

-Driving action-
Next, cold air operation of the air conditioner (1) of the above embodiment will be described. During the cold air operation of the air conditioner (1), the first fan (38) and the second fan (39) are in operation, and air flows through the first passage (41) and the second passage (42), respectively. Further, the compressor (40) is in an operating state, and the refrigerant is circulated in the refrigerant circuit to perform a refrigeration cycle. As a result, the first heat exchanger (36) functions as an evaporator, and the second heat exchanger (37) functions as a condenser. Further, the motor of the drive gear (70) enters the operating state, and the suction rotor (50) rotates in the clockwise direction.

  In the first passage (41), the air sucked from the rear suction port (23) is blown out from the discharge port of the first fan (38) to the upper passage (45). This air passes from the rear toward the front through the vent holes in the upper half of the adsorption rotor (50). In the adsorption rotor (50) on the first passage (41) side, moisture in the air is adsorbed and the air is dehumidified.

  The air dehumidified as described above flows into the blowing passage (43) and passes through the first heat exchanger (36). In the first heat exchanger (36), heat in the air is taken away as heat of evaporation of the refrigerant. As a result, this air is cooled. The air cooled as described above is supplied from the air outlet (21) toward the office worker in a predetermined wind direction.

  The air cooled by the first heat exchanger (36) is dehumidified by the adsorption rotor (50). For this reason, at the time of air cooling by the 1st heat exchanger (36), it is controlled that moisture in the air will dew condensation. That is, the air conditioner (1) of the present embodiment can realize a cold air operation without drain.

  In the second passage (42), air sucked from the front suction port (22) flows into the suction passage (44). This air passes through the second heat exchanger (37). In the second heat exchanger (37), the heat of condensation of the refrigerant is released to the air. As a result, this air is heated. The air heated as described above passes from the front toward the rear through the vent holes in the lower half of the adsorption rotor (50). In the adsorption rotor (50) on the second passage (42) side, the adsorbent that has adsorbed moisture on the first passage (41) side is heated by air, and this moisture is released to the air. That is, the adsorption rotor (50) on the second passage (42) side is heated and regenerated by air.

  The air regenerated by heating the adsorption rotor (50) as described above flows through the storage chamber (47) via the second fan (39). Thereafter, this air is blown out from the exhaust port (24) to the upper outside of the casing (10). The sensible heat and latent heat of the air thus exhausted are processed by an air conditioner or the like provided on the ceiling of the office.

<Rotation operation of suction rotor>
As described above, during the cold air operation of the air conditioner (1), the adsorption rotor (50) is heated to regenerate the adsorption rotor (50). For this reason, the base material (51) and the annular member (57) may thermally expand as the suction rotor (50) rises in temperature. If the suction rotor (50) cannot be moved in the radial direction when the suction rotor (50) is thermally expanded in this way, the sliding resistance between the suction rotor (50) and the frame (60) increases. As a result, the power of the drive gear (70) for rotating the suction rotor (50) also increases. Therefore, in the present invention, the inner peripheral surface of the holding portion (62) does not increase the sliding resistance between the adsorption rotor (50) and the frame body (60) even during the thermal expansion of the adsorption rotor (50). A notch groove (65) is formed in.

  Since the suction rotor (50) shown in FIG. 6 is pressed against the guide portion (63) by its own weight, it is always supported by the inner peripheral surface of the guide portion (63). For this reason, even when the suction rotor (50) rotates, the outer peripheral surface of the suction rotor (50) and the inner peripheral surface of the guide portion (63) come into sliding contact, and the suction rotor (50) is moved by the guide portion (63). Always guided in the circumferential direction. As a result, the suction rotor (50) rotates stably inside the frame (60).

  On the other hand, when the base member (51) and the annular member (57) are thermally expanded by the heated air during the rotation of the suction rotor (50), the suction rotor (50) is greatly slidably in contact with the guide portion (63). Displacement towards diameter (64). That is, the suction rotor (50) is displaced with the notch groove (65) as a relief space while maintaining sliding contact with the guide portion (63). For this reason, even during the thermal expansion of the suction rotor (50), an increase in sliding resistance between the suction rotor (50) and the frame (60) is avoided, and the suction rotor (50) is located inside the frame (60). Rotates stably. The thickness dimension and circumferential angle of the notch groove (65) are optimally designed according to the expansion coefficient of the base material (51) and the annular member (57), the temperature of the heated air, and the like. .

-Effect of the embodiment-
In the present embodiment, a guide portion (63) is provided on the holding portion (62) of the frame (60) so as to slide in contact with the suction rotor (50) and guide the suction rotor (50) in the circumferential direction. For this reason, the adsorption rotor (50) can be rotated without providing a rotation shaft at the axis of the adsorption rotor (50). At this time, since the guide portion (63) is provided near the lower side of the suction rotor (50), the rotating suction rotor (50) can be always supported by the guide portion (63). 50) can be rotated stably.

  On the other hand, the holding part (62) has a large diameter part (64) formed by a notch groove (65). For this reason, at the time of thermal expansion of the adsorption rotor (50), the adsorption rotor (50) is displaced toward the notch groove (65). Therefore, an increase in sliding resistance between the suction rotor (50) and the frame (60) can be avoided. As a result, the power of the drive gear (70) can be reduced, or the drive gear can be made compact. Further, the adsorption rotor (50) can be rotated stably, and the reliability of the air conditioner (1) can be improved. Furthermore, the wear and deterioration of the outer peripheral surface of the adsorption rotor (50) can be suppressed, and the life of the adsorption rotor (50) can be extended.

  In the present embodiment, the drive gear (70) is disposed at a circumferential angle of about 100 degrees when the upper end of the suction rotor (50) is used as a reference. On the other hand, the guide part (63) is formed over a range of a circumferential angle of 135 degrees to 285 degrees. That is, the guide part (63) is also formed on the substantially opposite side from the position of the drive gear (70) with the suction rotor (50) interposed therebetween. For this reason, when the suction rotor (50) is rotated, even if a force directed from the drive gear (70) in the axial direction of the suction rotor (50) acts on the suction rotor (50), it faces the drive gear (70). The guide portion (63) at the position to be used serves as a stopper, and the suction rotor (50) is held. Therefore, the meshing between the drive gear (70) and the suction rotor (50) can be stabilized.

  Furthermore, in this embodiment, a fluororesin film is formed on the sliding portion of the frame (60) with the suction rotor (50). For this reason, the sliding resistance of the sliding contact portion between the frame (60) and the suction rotor (50) can be reduced. Therefore, the power of the suction rotor (50) can be effectively reduced, and the drive source of the suction rotor (50) can be made more compact.

  Moreover, in the said embodiment, as shown in FIG. 5, the adsorption | suction rotor (50) and the frame (60) are arrange | positioned in the casing (10) in the attitude | position inclined about 30 degree | times from the perpendicular direction. The frame (60) has an inner plate portion (61a) inside the holding portion (62). For this reason, the weight of the suction rotor (50) also acts on the inner plate portion (61a), and the suction rotor (50) can be stably held by the frame (60). Further, the first partition plate (31) is also inclined about 30 degrees from the vertical direction and formed on the diagonal line of the casing (10). For this reason, the space of the upstream and downstream of the adsorption | suction rotor (50) divided by the 1st partition plate (31) can be taken widely. Therefore, the heat exchanger (36, 37), the fan (38, 39) and the like can be stored in a compact manner, and the air conditioner (1) can be made compact.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  In the said embodiment, the frame (60) is provided in the outer peripheral whole region of the adsorption | suction rotor (50), and the adsorption | suction rotor (50) is hold | maintained inside a frame (60). However, while providing a guide portion (63) that is in sliding contact with a half or less of the lower outer peripheral surface of the suction rotor (50), the upper outer peripheral surface of the suction rotor (50) is opened, and the guide portion (63 ) May support the suction rotor (50). Also in this case, when the adsorption rotor (50) is thermally expanded, the adsorption rotor (50) can be displaced to the open side, and an increase in sliding resistance between the adsorption rotor (50) and the guide portion (63) can be avoided. .

  Moreover, in the said embodiment, the adsorption | suction rotor (50) and the frame (60) are arrange | positioned in the casing (10) with the attitude | position inclined about 30 degree | times from the perpendicular direction. However, the adsorption rotor (50) and the frame (60) may be arranged upright in the vertical direction, or arranged in a posture inclined from the vertical direction to the horizontal direction at a different angle from the above embodiment. You may do it.

  In the above embodiment, the suction rotor (50) is driven to rotate by the drive gear (70). However, for example, a belt may be wound around the outer periphery of the suction rotor (50), and the suction rotor (50) may be driven by rotating the belt with a geared motor or the like.

  Furthermore, in the said embodiment, although the adsorption | suction rotor (50) is applied to the drainless air conditioner (1), this adsorption | suction rotor (50) performs the dehumidifier which dehumidifies indoor space, and humidifies indoor space. You may apply to a humidifier etc.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a humidity control apparatus including an adsorption rotor that rotates while straddling two air passages.

It is the perspective view which looked at the air conditioner to which the humidity control apparatus of this embodiment is applied from the front. It is the perspective view which looked at the air conditioner from back. It is the figure which looked at the inside of an air conditioner from the right side. It is a disassembled perspective view of the state which removed the adsorption rotor from the frame. It is a vertical sectional view of a suction rotor and a frame. It is the figure which looked at the adsorption | suction rotor from the front side.

Explanation of symbols

1 Air conditioner
10 Casing
41 First passage
42 Second passage
50 Suction rotor
60 frame
63 Guide part (small diameter part)
64 Large diameter part
65 Notch groove (gap)
70 Drive gear

Claims (7)

The first passage (41) includes a casing (10) having first and second passages (41, 42) through which air flows, and an adsorption rotor (50) that rotates while straddling both passages (41, 42). A humidity control device that adsorbs moisture in the air flowing through the adsorption rotor (50) and heats and regenerates the adsorption rotor (50) with air flowing through the second passage (42),
A humidity control apparatus comprising a guide portion (63) that slides in contact with a portion of the outer peripheral surface of the suction rotor (50) that is less than half of the circumferential direction and guides the suction rotor (50) in the circumferential direction. In claim 1,
The adsorption rotor (50) is arranged in a posture in which the axis of the adsorption rotor (50) is horizontal or oblique.
The humidity control apparatus, wherein the guide part (63) is at least in sliding contact with the lower outer peripheral surface of the adsorption rotor (50). In claim 2,
An annular frame (60) surrounding the outer periphery of the adsorption rotor (50);
The frame (60) has a small-diameter portion whose inner peripheral surface is an arc surface and is in sliding contact with the outer peripheral surface of the suction rotor (50), and the inner peripheral surface has a larger radius of curvature than the inner peripheral surface of the small-diameter portion. A large-diameter portion (64) that forms an arc surface and forms a gap (65) between the suction rotor (50) and the outer periphery;
A humidity control apparatus, wherein the small diameter part of the frame (60) constitutes a guide part (63). In claim 3,
A humidity control apparatus, wherein the frame (60) is formed with a fluororesin film at a sliding contact portion with the adsorption rotor (50). In claim 2,
The suction rotor (50) has a plurality of teeth formed on its outer peripheral side,
A humidity control apparatus comprising a drive gear (70) that meshes with teeth on the lower outer peripheral surface of the suction rotor (50) to rotate the suction rotor (50). In claim 5,
The humidity control apparatus, wherein the guide portion (63) is formed at least on the substantially opposite side of the drive gear (70) with the suction rotor (50) interposed therebetween. The first passage (41) includes a casing (10) having first and second passages (41, 42) through which air flows, and an adsorption rotor (50) that rotates while straddling both passages (41, 42). A humidity control device that adsorbs moisture in the air flowing through the adsorption rotor (50) and heats and regenerates the adsorption rotor (50) with air flowing through the second passage (42),
A guide part (63) for slidingly contacting a part of the outer peripheral surface of the suction rotor (50) and guiding the suction rotor (50) in the circumferential direction;
The humidity control apparatus, wherein the guide part (63) is in a non-contact state with a part of the outer peripheral surface of the adsorption rotor (50) that extends over half of the circumferential direction.

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