JP2008126205A - Dehumidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely prevent leakage of surely dehumidified condensed water without lowering dehumidification efficiency. <P>SOLUTION: The dehumidifier is provided with: a casing 10 demarcated inside into a dehumidifying passage 11 and a regeneration passage 12; a dehumidifying rotor 52 rotatably disposed straddling over both passages 11, 12; a rotor cover 59 disposed at one end of the regeneration passage 12 divided by the dehumidifying rotor 52; heat exchangers 67A, 67B connected to the rotor cover 59 and removing moisture contained in regenerated air by cooling the regenerated air flowing inside by air flowing outside; a heater 98 heating the regenerated air and dehumidifying rotor 52; a regenerated air circulation fan 102 circulating the regenerated air; and an indoor air circulation fan 105 sucking air in the room and circulatingly supply to the room, wherein a water receiving part 45 receiving condensed water condensed near the rotor cover 59 is provided to be located at least on the lower part of the rotor cover 59. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a dehumidifier.

  Prior art document information related to the dehumidifier of the present invention includes the following.

JP 2004-286276 A

  In this patent document, the inside of the casing is partitioned into a dehumidification passage and a regeneration passage, and a dehumidification is provided in which a heat exchanger, a dehumidification rotor, and an indoor air circulation fan are stacked in the horizontal direction from the indoor air suction side. The machine is listed. Among them, the dehumidification rotor has a disk shape, and is arranged so that its rotation axis extends in the horizontal direction, and is rotated by the driving means.

  The casing includes a base for fixing the components and a pair of covers for closing both surfaces of the base. The base is provided with a dehumidification rotor and a heat exchanger stacked on one side, and an indoor air circulation fan is provided on the other side. The base is provided with a duct portion that constitutes a regeneration passage. This duct portion extends in a substantially inverted L shape upward from a connection portion with the outlet of the heat exchanger located on the lower side, and a tip of the duct portion serves as a heater cover that houses a heater that heats the regeneration air and the dehumidifying rotor. It is configured to connect. The dehumidifying rotor is provided with a rotor cover so as to be located on the opposite side of the heater cover, and this rotor cover is connected to the inlet of the heat exchanger.

  In the dehumidifier configured as described above, in the dehumidifying passage, the sucked indoor air is passed through the dehumidifying rotor so that the moisture contained in the indoor air is adsorbed by the dehumidifying rotor, and dried air enters the room from the exhaust port. Circulating supply. In the regeneration passage, the internal regeneration air is heated by a heater, and the moisture desorbed by the dehumidification rotor is released by passing through the dehumidification rotor in this state, and the moisture is contained in the regeneration air. Thereafter, when the regenerated air passes through the heat exchanger, moisture is condensed by being cooled by heat exchange with room air that passes outside the heat exchanger, and the moisture contained in the regenerated air is Removed and condensed water is collected in a tank.

  However, the regeneration passage is divided by a dehumidification rotor that is rotatably disposed across the dehumidification passage. Further, the regenerative air that passes through the dehumidifying rotor and flows into the rotor cover is in a state containing a large amount of moisture. In the rotor cover, it is very difficult to allow all of the regenerated air that has passed through the dehumidification rotor to flow in due to the rotation of the dehumidification rotor. Therefore, when a part of the regenerated air cannot flow into the rotor cover and leaks into the dehumidifying passage, the regenerated air is cooled by room air having a temperature lower than that of the regenerated air. As a result, there is a problem that moisture contained in the regenerated air is condensed and the condensed water leaks out of the casing.

  In order to solve this problem, it is conceivable to provide a dedicated drainage structure on the rotor cover front side in the rotational direction of the dehumidifying rotor. In this case, this drainage structure (pipe, etc.) Since it arrange | positions so that a part of dehumidification channel | path may be interrupted | blocked, the distribution | circulation efficiency in a dehumidification channel | path may fall and it may reduce dehumidification efficiency.

  This invention is made | formed in view of the conventional problem, and makes it a subject to provide the dehumidifier which can prevent the leakage of the dew condensation water reliably dehumidified, without reducing dehumidification efficiency.

  In order to solve the above-mentioned problems, a dehumidifier according to the present invention is rotated by a driving means centering on a casing whose interior is divided into a dehumidifying passage and a regeneration passage, and a rotational axis extending in a substantially horizontal direction across both the passages. A dehumidification rotor that can be disposed, a rotor cover that is disposed at one end of the regeneration passage divided by the dehumidification rotor, and a portion of the regeneration passage that is connected to the rotor cover and circulates in the interior. A heat exchanger that cools the regeneration air with the air flowing outside to remove moisture contained in the regeneration air, a heater that is disposed in the regeneration passage and heats the regeneration air and the dehumidification rotor, and the regeneration A regenerative air circulation fan that is arranged in the passage and circulates the regenerative air from the heater through a heat exchanger, and a regenerative air circulation fan that is arranged in the dehumidification passage, sucks indoor air, and dehumidifies by the dehumidification rotor. In a dehumidifier equipped with an indoor air circulation fan that circulates and supplies dry air to the room, a water receiving part that receives condensed water condensed around the rotor cover so as to be positioned at least at the lower part of the rotor cover The configuration is provided.

  In this dehumidifier, the regeneration air leaks from the rotor cover that is the re-inflow end of the regeneration passage divided by the dehumidification rotor and can be received by the water receiver even if dew condensation occurs in the dehumidification passage. Unintentional leakage of water can be reliably prevented.

  In this dehumidifier, it is preferable that the lower part of the heat exchanger is positioned by the water receiver. If it does in this way, while the arrangement work nature of a heat exchanger can be improved, the arrangement position can be stabilized.

  Moreover, it is preferable to provide the water receiving portion so as to cover the entire lower portion of the heat exchanger. If it does in this way, even if condensed water leaks from a heat exchanger by secular change, since it can receive in a water receiving part, it can prevent that water leaks from a dehumidifier.

  The casing includes a base that extends in a substantially vertical direction, a first cover that closes one horizontal surface of the base, and a second cover that closes the other horizontal surface of the base. A duct part, which is connected to the outlet of the heat exchanger and forms a part of the regeneration passage, is recessed in the lower part so as to extend in a substantially horizontal direction, and the duct cover that closes the opening end of the duct part It is preferable to integrally mold the water receiving portion. In this way, it is possible to reduce the number of parts, and it is possible to prevent a member that becomes a flow resistance of the sucked air from being located in the dehumidifying passage.

  In the dehumidifier of the present invention, the water receiver is provided at the lower part of the rotor cover where regenerated air may leak and condensate water may be generated, so even if condensation occurs in the dehumidification passage, It is possible to reliably prevent unintended leakage of water from the dehumidifier.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a dehumidifier according to an embodiment of the present invention. This dehumidifier roughly divides the inside of a casing 10 formed of a hexahedron that is long in the height direction and whose depth in the front-rear direction is thinner than the width in the left-right direction into a dehumidification passage 11 and a regeneration passage 12, and a dehumidification rotor 52 is provided in the inside. And a heat exchanger 67A, 67B, a heater 98, a regenerative air circulation fan 102, and an indoor air circulation fan 105 are stacked in a horizontal direction and a tank 107 is disposed in the lower part. is there.

  2 and 3, the casing 10 has a front cover (first cover) 13 disposed on the front (one) surface of the base 31, and a rear cover (second cover) on the rear (other) surface. ) 17 and a top cover (third cover) 25 is disposed on the upper part.

  First, an exhaust port 14 that is opened and closed by a rotatable louver 26 is formed in the upper portion of the front cover 13. Further, a partition wall 15 constituting an involute passage is provided on the inner surface of the front cover 13 so as to guide air toward the exhaust port 14. Further, a mounting base 16 is provided at the lower portion of the front cover 13.

  The rear cover 17 is provided with a concave portion 18 that is recessed inward, and an air inlet 19 that includes a plurality of slits extending in the vertical direction is formed in the concave portion 18. And the filter member 20 is arrange | positioned by this recessed part 18 so that attachment or detachment is possible. The filter member 20 is provided with an air inlet 21 composed of a plurality of slits, and a filter (not shown) is disposed on the inner surface. Further, a similar pedestal portion 22 that engages with the pedestal portion 16 of the front cover 13 is provided at the lower portion of the rear cover 17, and a mounting port 23 for disposing the tank 107 is provided above the same. Yes. The tank cover chamber 24 is formed in the lower part of the casing 10 by assembling the rear cover 17 and the front cover 13 to the base 31.

  The top cover 25 includes a rotatable louver 26 that opens and closes the exhaust port 14. The top cover 25 is provided with a housing portion for a rotatable carrying handle 27 and an operation panel 30 including a switch 28 and a display portion 29.

  As shown in FIGS. 3 and 4, the base 31 includes a dehumidifying rotor 52, heat exchangers 67A and 67B, a heater 98, a regenerative air circulation fan 102, and an indoor air circulation fan 105 which will be described later. It is. The base 31 is provided with frames 31 a to 31 d protruding in the front-rear direction on the upper, lower, left and right edges of a substantially rectangular flat plate extending in the vertical direction. In the base 31, a handle mounting part 32 for assembling the handle 27 rotatably is provided on the upper frame 31 a. Further, frame pieces 33 located on the inner surface of the tank housing chamber 24 are provided on both sides of the lower frame 31 b of the base 31.

  The base 31 is provided with a dehumidifying rotor arrangement portion 34 having a circular opening near the upper frame 31a in the center. The dehumidifying rotor arrangement portion 34 is provided with a positioning step 35 in which the (one surface) side of the front cover 13 is larger in diameter than the (other surface) side of the rear cover 17. A rotor 52 is provided. In other words, the base 31 of the present embodiment is provided with an opening that is not provided with any member that hinders ventilation. Therefore, when the same indoor air circulation fan 105 is used, the amount of air flowing through the dehumidifying passage 11 can be increased compared to the conventional case. Note that an indoor air circulation fan 105 is disposed further on the front side of the dehumidifying rotor 52.

  Further, a rotor cover disposition portion 36 is provided on the front surface (one surface) side of the base 31 so as to be positioned at the edge of the dehumidification rotor disposition portion 34 in the upper left portion. Further, a regeneration air circulation fan arrangement portion 37 is provided on the front side of the base 31 so as to be positioned on the lower left side of the dehumidification rotor arrangement portion 34. The regeneration air circulation fan disposing portion 37 is provided with a boss 38 for screwing the fan case 103 surrounding the regeneration air circulation fan 102.

  Furthermore, on the rear surface (other surface) side of the base 31, as shown in FIG. 3 and FIGS. 5A and 5B, the heat exchangers 67A and 67B are penetrated to be positioned and arranged. A positioning cylinder portion 39 is projected. In addition, a duct portion 40 extending in the horizontal direction in the left-right direction is provided at the lower portion of the dehumidifying rotor arrangement portion 34. The duct portion 40 constitutes a part of the regeneration passage 12, has a bowl shape that is recessed so as to be recessed toward the front side, and is located at a position corresponding to the regeneration air circulation fan arrangement portion 37. Is provided with a circular vent 41.

  A separate duct cover 42 is fixed to the opening end on the rear side of the duct portion 40 by screws. The duct cover 42 matches the shape of the open end of the duct portion 40, and an inlet 43 is provided at a position corresponding to a first outlet 77 of a heat exchanger 67A described later. A screw hole 44 for fixing heat exchangers 67A and 67B, which will be described later, is provided around the inlet 43.

  The lower part of the duct cover 42 according to the present embodiment receives not only the lower part of the rotor cover 59 but also the horizontal widths of the heat exchangers 67A and 67B and the entire depth of the stacked front and rear direction (see FIG. 6). A water receiving portion 45 that extends so as to cover substantially the entire left and right direction of the base 31 and receives condensed water is integrally formed. The water receiving portion 45 has a bowl shape, and the rising surface 46 on the rear cover 17 side serves to position and hold the lower portion of the heat exchanger 67B located outside. Moreover, the water receiving part 45 makes the position corresponding to the drain parts 71 and 88 of heat exchanger 67A, 67B the lowest position, and the water flow hole 47 is provided in the position. The water passage hole 47 also serves as a drain hole for draining the condensed water received by the water receiving portion 45 to the sub tank 50.

  Here, in the present embodiment, a portion where the regeneration air may leak from the regeneration passage 12, that is, a portion where unintended dew condensation water is generated, is dehumidified rotor arrangement portion 34 that is divided by the dehumidification rotor 52 described later. Is around. For this reason, in this embodiment, the dehumidifying rotor disposing portion 34 is provided with a contact portion 35a on the positioning step portion 35 so as to protrude substantially annularly toward the center at the rear side end portion. The arrangement portion 36 and the region located below the arrangement portion 36 are formed in a state of being recessed toward the front side without providing the contact portion 35a. The duct cover 42 is provided with a recess 42a that is flush with the contact portion 35a, so that the area where the recess 42a is provided is substantially flush with the opening end of the rotor cover 59 described later. It is configured to be. Thereby, the water condensed around the rotor cover 59 can be reliably guided to the water receiver 45.

  In the lower frame 31b of the base 31, a similar water hole 48 is provided at a position corresponding to the upper and lower sides of the water hole 47, and a sub tank 50 having a water stop valve 49 is provided below the water hole 48. Yes. 2 and 5A, the lower frame 31b is provided with a water passage hole 51 for draining water condensed in the duct portion 40 to the sub tank 50 in the same manner. The water stop valve 49 is connected to an open / close mechanism (not shown) that opens when the tank 107 is attached and closes when the tank 107 is removed. Further, the water passage hole 47 of the duct cover 42 is provided with a rib (not shown) penetrating through the water passage hole 48 of the lower frame 31b.

  The dehumidifying rotor 52 is rotatably arranged across both the passages 11 and 12 so that about 3/4 is located in the dehumidifying passage 11 and about 1/4 is located in the regeneration passage 12. It is. As shown in FIG. 3, the dehumidifying rotor 52 is obtained by holding a rotor main body 53 made of a mesh-like ceramic honeycomb bonded with zeolite or silica gel by a holding member 54 made of resin. As shown in FIG. 4, the holding member 54 includes a bearing portion 55 located at the center of the rotor main body 53, an outer wall portion 56 located at the outer peripheral portion of the rotor main body 53, and a connecting frame 57 that connects them. ing. The holding member 54 is disposed from the front cover 13 side, which is one side with respect to the base 31, so that the connecting frame 57 is positioned adjacent to a heat exchanger 67 </ b> A described later. In the present embodiment, the bearing portion 55 is provided with a conical bearing hole 55a in which the diameter on the connection frame 57 side is larger than the diameter on the front cover 13 side. Further, the outer wall portion 56 has an outer diameter smaller than the diameter of the small diameter portion of the positioning step portion 35 of the dehumidifying rotor arrangement portion 34. Then, a plurality of protruding teeth 58 are projected so as to form a flange shape that is larger than the diameter of the small diameter portion of the positioning step portion 35 and smaller than the diameter of the large diameter portion so as to be positioned on the front cover 13 side. Yes. The ridges 58 mesh with a gear disposed on an output shaft of a motor (not shown) which is driving means.

  The dehumidifying rotor 52 is disposed from the same direction after the rotor cover 59 is disposed from the front side with respect to the rotor cover disposing portion 36 of the base 31. Thereafter, a heater cover 99 that houses and arranges the heater 98 is disposed so as to be positioned on the opposite side of the rotor cover 59 with respect to the dehumidifying rotor 52. That is, since the dehumidification rotor 52 is disposed across both the passages 11 and 12, the regeneration passage 12 is divided by the dehumidification rotor 52. A heater cover 99 is disposed on the upstream side (the other end) of the divided regeneration passage 12, and a rotor cover 59 is disposed on the downstream side (one end).

  As shown in FIGS. 4, 5 and 7, the rotor cover 59 has a fan shape that closes about 3/4 of the dehumidifying rotor arrangement portion 34, and has an edge corresponding to a part of the circle. Is provided with a fixed edge portion 60 which is fixed to the rotor cover arrangement portion 36 by screws. The fixed edge portion 60 has a stepped shape that coincides with the positioning step portion 35 of the dehumidifying rotor arrangement portion 34, and is configured such that the rotor cover 59 protrudes toward the rear cover 17 with respect to the base 31 in the mounted state. Has been. Further, a positioning piece 61 that further protrudes toward the front cover 13 is provided on the outer peripheral edge of the fixed edge portion 60 of the present embodiment.

  Further, the rotor cover 59 is provided with a fan-shaped bulging portion 62 so as to bulge toward the rear cover 17, and the bulging portion 62 is connected to a first inlet 75 of a heat exchanger 67A described later. Correspondingly, a connection port 63 through which the regeneration air flows is provided. At the edge of the connection port 63, a connection rib 64 is provided so as to be fitted into the first inflow port 75. Further, the bulging portion 62 is provided with a screw hole 65 for screwing the heat exchangers 67A and 67B so as to be positioned on the outer peripheral portion of the connection port 63.

  In the rotor cover 59 of the present embodiment, a rotating shaft 66 on which the dehumidifying rotor 52 is rotatably mounted is integrally formed at the top portion located at the center of the circular dehumidifying rotor arrangement portion 34. The rotating shaft 66 extends in the horizontal direction toward the front cover 13, and is tapered toward the front end by making the rear cover 17 side, which is the base thereof, larger in diameter than the front cover 13 side, which is the front end. It is formed in a substantially conical shape. By disposing the dehumidifying rotor 52 on the rotating shaft 66, the dehumidifying rotor 52 can be rotated about the rotating shaft 66 extending in the horizontal direction as an axis (center).

  As shown in FIG. 6, the heat exchangers 67 </ b> A and 67 </ b> B are disposed on the side of the rear cover 17, which is the other side of the base 31, in the dehumidifying passage 11. It constitutes. These heat exchangers 67A, 67B are made of resin in which a pair of panels 68A, 68B, 85A, 85B formed in a symmetrical shape are welded as shown in FIGS. 8 and 9 by vacuum forming or pressure forming.

  Specifically, the first panels 68A and 68B of the inner heat exchanger 67A disposed on the dehumidifying rotor 52 side are provided with a plurality of first partitioning concaves positioned symmetrically to each other as shown in FIG. The strips 69A and 69B are formed, and a plurality of first flow paths 70 through which the regeneration air passes are formed by portions other than the first partitioning concave strips 69A and 69B. The first flow path 70 is inclined so that the position corresponding to the water passage hole 47 is the lowest position, and a first drain portion 71 is provided at that position. In addition, a first through hole 72 for circulating air sucked from the room is provided in the portion of the first partitioning recesses 69A and 69B that are bonded together. Further, a first positioning hole 73 is provided at a position corresponding to the positioning cylinder portion 39 so as to avoid the first flow path 70.

  On the other hand, of the first panels 68A and 68B, the first panel 68A positioned on the dehumidifying rotor 52 side is provided with a recess 74 that matches the shape of the bulging portion 62 of the rotor cover 59. A first inflow port 75 is provided therein. The first panel 68 </ b> B is provided with a first connection port 76 having a smaller diameter than the first inlet 75 at a position facing the first inlet 75. In the first panel 68 </ b> A, a first outlet 77 corresponding to the inlet 43 of the duct cover 42 is provided at a diagonal position with respect to the first inlet 75. The first panel 68B is provided with a second connection port 78 having the same diameter as that of the first outlet 77 at a position facing the first outlet 77. Further, the duct covers 42 are provided on the first panels 68A and 68B at opposite positions around the first inlet 75 and the first connection port 76 and opposite positions around the first outlet 77 and the second connection port 78, respectively. A first screw insertion hole 79 for screwing into the screw holes 44 and 65 of the rotor cover 59 is provided.

  In the present embodiment, the first reinforcing connection member 80A is disposed between the first inflow port 75 and the first connection port 76 that face each other in the front-rear direction, and the first outflow port 77 and the second connection port. A first reinforcing connecting member 80B is disposed between the first reinforcing connecting member 80B and the first reinforcing connecting member 80B. That is, the heat exchanger 67A is configured to weld (interior) the first panels 68A and 68B with the first reinforcing connection members 80A and 80B sandwiched between the first panels 68A and 68B.

  The first reinforcing connection members 80A and 80B are cylindrical ones made of a flame retardant resin material, and the first communication hole 81 for communicating with the first flow path 70 of the heat exchanger 67A is provided on the outer peripheral surface thereof. Are provided at predetermined intervals in the circumferential direction. In addition, in the first reinforcing connection members 80A and 80B, the first arm portion 82 having an insertion hole 82a corresponding to the first screw insertion hole 79 at a position excluding the first communication hole 81 is radially formed. It protrudes outward. Among these first reinforcing connection members 80A and 80B, the first reinforcing connection member 80A on the inflow side is set to a first connection port 76 by setting the size of the diameter of the first inflow port 75 and the diameter of the first connection port 76. A ring-shaped closing portion 83 is provided on the arrangement side. A connecting rib 84 is provided on the inner peripheral edge of the closing portion 83 to be fitted in a second reinforcing connecting member 94A described later and connected in an airtight manner. The closing portion 83 prevents all the regenerative air that has flowed into the first reinforcing connecting member 80A along the axial direction from flowing into the heat exchanger 67B on the downstream side, and the heat exchanger It becomes the flow resistance which flows into 67A.

  Further, as shown in FIG. 9, the second panels 85A and 85B of the outer heat exchanger 67B disposed on the rear cover 17 side so as to overlap with the heat exchanger 67A have the first panel 68A, Similarly to 68B, a plurality of second partitioning recesses 86A and 86B are formed symmetrically with each other, and a plurality of second flow paths through which the regenerated air is allowed to pass through portions excluding these second partitioning recesses 86A and 86B. 87 is formed. The second flow path 87 is inclined so that the position corresponding to the water passage hole 47 is the lowest position, and the second drain portion 88 is provided at that position. In addition, a second through-hole 89 for circulating air sucked from the room is provided in the bonded second partitioning recesses 86A and 86B. Further, a second positioning hole 90 is provided at a position corresponding to the positioning cylinder portion 39 so as to avoid the second flow path 87. The second flow path 87 and the second through hole 89 of the outer heat exchanger 67B are phased to the left and right with respect to the first flow path 70 and the first through hole 72 of the inner heat exchanger 67A. By configuring the air flowing in from the cover 17 to flow in a staggered pattern in the order of the second through-hole 89 and the first through-hole 72, a flow (heat exchange) time is secured.

  On the other hand, of the second panels 85A and 85B, the second inflow port 91 corresponding to the first connection port 76 of the heat exchanger 67A is provided in the second panel 85A located on the inner heat exchanger 67A side. The first connection port 76 has the same diameter. In addition, a second outlet 92 corresponding to the second connection port 78 of the heat exchanger 67A is provided at a diagonal position with respect to the second inlet 91. And in the 2nd panel 85B, the opening for connection or inflow / outflow is not provided in the position facing these. However, both of the second panels 85A and 85B are provided with second screw insertion holes 93 for screwing into the screw holes 44 and 65 of the duct cover 42 and the rotor cover 59.

  In the present embodiment, the second reinforcing connection member 94A is disposed between the second inlet 91 of the second panel 85A and the closed surface of the second panel 85B, and the second outlet of the second panel 85A. A second reinforcing connection member 94B is disposed between 92 and the closing surface of the second panel 85B. That is, the heat exchanger 67B welds these second panels 85A and 85B with the second reinforcing connection members 94A and 94B sandwiched between the second panels 85A and 85B, similarly to the heat exchanger 67A. ).

  The second reinforcing connection members 94A and 94B are cylindrical, made of a flame-retardant resin material, like the first reinforcing connection members 80A and 80B, and the second flow path of the heat exchanger 67B is formed on the outer peripheral surface thereof. Second communication holes 95 for communicating with 87 are provided at predetermined intervals in the circumferential direction. In addition, in the second reinforcing connection members 94A and 94B, the second arm portion 96 having insertion holes 96a corresponding to the second screw insertion holes 93 at positions excluding the second communication holes 95 is formed in a radial shape. It protrudes outward. Among these second reinforcing connection members 94A and 94B, the second reinforcing connection member 94A on the inflow side is provided with this high-temperature regeneration air in order to prevent deterioration due to continuous contact with the closed surface of the second panel 85B. A closing wall 97 is provided on the arrangement side to the second panel 85B.

  As shown in FIG. 10, the heater 98 is formed by winding a continuous coil of coil around a support frame made of a mica plate. The heater 98 is disposed on the side of the front cover 13 with respect to the dehumidifying rotor 52 via the heater cover 99. It is arranged. The heater 98 generates heat by power supplied from a power supply circuit (not shown), and heats the supplied regeneration air and the dehumidification rotor 52 disposed in the vicinity.

  As shown in FIGS. 10 and 11, the heater cover 99 has a fan shape with an opening on the dehumidifying rotor 52 side. The heater cover 99 is formed with a flange portion 100 that is substantially fan-shaped in line with the rotor cover 59 around the dehumidifying rotor 52 and whose outer peripheral edge coincides with the inner method of the positioning piece 61. Further, the heater cover 99 is provided with a connecting portion 101 on a lower outer peripheral surface located on the fan case 103 side described later. In the heater cover 99, the heater 98 is accommodated in a substantially half region on the connection portion 101 side that is the upstream side.

  The regenerative air circulation fan 102 is a sirocco fan that is rotated by a motor (not shown) that is a driving means, and is arranged on the regenerative air circulation fan arrangement portion 37 of the base 31 through the fan case 103 from the front cover 13 side. Established. The sirocco fan is a well-known one having a disk-shaped base, a plurality of blade portions projecting in a direction orthogonal to the base, and an annular connecting portion for connecting the tip outer peripheral portion of each blade portion. It is. The fan case 103 is fixed by screwing so as to cover the vent hole 41 of the base 31, and is connected to the connection portion 101 at the upper part located on the heater cover 99 side. Is provided.

  As shown in FIG. 3, the indoor air circulation fan 105 is a sirocco fan that is rotated by a drive motor (not shown) that is a drive means, and is positioned via a holding frame 106 so as to be positioned on the lower front side of the dehumidifying rotor 52. Fixed to the base 31. The sirocco fan that constitutes the indoor air circulation fan 105 is a well-known fan having a base, a plurality of blade portions, and a connecting portion, similar to the regeneration air circulation fan 102, and is larger than the regeneration air circulation fan 102. It differs only in the point which applied the thing.

  The tank 107 has a box shape with an upper surface opening for storing dehumidified condensed water drained from the sub tank 50. A rotatable float member is disposed inside the tank 107, and when the water level in the tank 107 rises, the float member floats to detect a full water state.

  The regeneration passage 12 of the dehumidifier configured as described above is partitioned by the fan case 103, the heater cover 99, the rotor cover 59, the heat exchangers 67 </ b> A and 67 </ b> B, and the duct portion 40 of the base 31, starting from the regeneration air circulation fan 102. Consists of states. Of the space excluding the regeneration passage 12, a space that extends from the rear cover 17 to the dehumidification rotor arrangement portion 34 of the base 31 and the partition 15 of the front cover 13 to the exhaust port 14 is a dehumidification passage 11. Configure.

  In the dehumidifier, when the power switch is turned on, the tank 107 is set in the casing 10 and the dehumidifier is not full, the dehumidification rotor 52, the heater 98, the regenerative air circulation fan 102, and the indoor air circulation fan. Electric power is supplied to 105 to start dehumidifying operation. Further, when the tank 107 becomes full, the energization of each component is stopped and the dehumidifying operation is stopped.

  In addition, the dehumidifier of this embodiment is equipped with drying functions such as futons and shoes. As shown in FIGS. 12 and 13, this drying function is executed in a state where a cord member 108 for bundling a power cord (not shown) is used and a cover member 112 and a pipe member 114, which are separate accessory parts, are mounted. It is.

  The cord holder 108 has a substantially J shape with a locking piece 110 inserted and locked in a locking hole 109 provided on the side surface of the front cover 13 at the upper end. The upper end of the cord holder 108 is provided with a mounting portion 111 having an upper end opening for positioning and holding the pipe member 114.

  The cover member 112 exposes the operation panel 30 and the handle 27 located on the rear side in the top cover 25 and covers the louver 26 located on the front side from the exhaust port 14 of the front cover 13. The cover member 112 is provided with a flow-curved depression 113 on the rear surface side in consideration of workability that the user grips with the handle 27 in the mounted state. Further, in the cover member 112, a receiving portion (not shown) for inserting and locking the pipe member 114 is provided inside the left end.

  The pipe member 114 is a pipe having a substantially elliptical horizontal cross section extending from the receiving portion to the mounting portion 111, and a hose connection portion 115 protruding in a cylindrical shape in the lateral direction is provided at a lower end portion thereof. ing. A mounting piece 116 to be inserted into the mounting portion 111 is projected downward from the lower end of the hose connection portion 115. Here, the hose connection part 115 is configured to be positioned below the center of gravity of the dehumidifier. Therefore, the dehumidifier itself is not easily overturned even if the hose is moved in a state in which a separate soft hose (not shown) is attached to the hose connection portion 115.

  Next, the dehumidifying operation by the dehumidifier will be specifically described.

  First, in the dehumidifying passage 11, indoor air is sucked from the intake port 19 of the rear cover 17 by driving the indoor air circulation fan 105. Then, when the sucked air passes through the through holes 72 and 89 of the heat exchangers 67A and 67B, it is heated by heat exchange with the regenerated air passing through the internal flow paths 70 and 87, and in this state When passing through the dehumidifying rotor 52, the contained moisture is adsorbed. Thus, the air is circulated and supplied from the exhaust port 14 of the front cover 13 into the room as dry air.

  On the other hand, in the regeneration passage 12, internal regeneration air flows from the fan case 103 into the heater cover 99 containing the heater 98 by driving the regeneration air circulation fan 102. Thus, the regenerated air is heated by the heater 98 and then adsorbs the moisture adsorbed by the dehumidifying rotor 52 when passing through the dehumidifying rotor 52. Next, almost all of the regenerated air is recovered by the rotor cover 59 and flows into the heat exchanger 67A. In this heat exchanger 67A, the closed portion 83 of the first reinforcing connecting member 80A distributes the heat exchanger 67A to the inner heat exchanger 67A and the outer heat exchanger 67B. It flows toward 92. At this time, it is cooled by heat exchange due to a temperature difference from the air sucked from the room flowing through the dehumidifying passage 11, and moisture contained in the regenerated air is condensed. The condensed water is drained from the drain portions 71 and 88 of the heat exchangers 67 </ b> A and 67 </ b> B to the sub tank 50 and is collected from the sub tank 50 to the tank 107. In addition, the regenerated air that has flowed out of the heat exchangers 67A and 67B is in a substantially dry state, flows into the duct portion 40, and is supplied again to the heater 98 side by the regenerative air circulation fan 102.

  The dehumidifier of the present embodiment includes reinforcing connection members 80A, 80B, 94A, and 94B in the inflow ports 75 and 91 and the outflow ports 77 and 92 in the heat exchangers 67A and 67B made of a pair of resin sheets. Therefore, the connection state between the heat exchangers 67A and 67B made of different parts, the rotor cover 59, and the duct portion 40 can be stabilized. As a result, since the airtight performance of the regeneration passage 12 can be improved and sufficient airtight performance can be ensured, the temperature drop of the regenerated air can be suppressed and the dehumidification efficiency can be improved.

  Further, since the rotary shaft 66 on which the dehumidifying rotor 52 is rotatably mounted is formed in a tapered conical shape toward the heater 98, the dehumidifying rotor 52 is brought closer to the heater 98 regardless of the inclined state. Can be maintained. As a result, since the heating performance of the dehumidification rotor 52 can be stabilized, the dehumidification efficiency can be improved.

  As described above, the dehumidifier of the present invention is designed so that the regeneration passage 12 has sufficient airtight performance, and the heating efficiency of the regeneration air can be improved. However, in the portion divided by the dehumidifying rotor 52, the regeneration air may leak out at the re-inflow end to the regeneration passage 12. In consideration of this possibility, in this embodiment, the opening area of the bulging portion 62 of the rotor cover 59, which is the re-inflow end, is sufficiently designed. However, there is a possibility of leakage.

  However, in the present embodiment, since the water receiving portion 45 is provided so as to receive not only the lower region of the rotor cover 59 but also the entire lower portion of the heat exchangers 67A and 67B, the dehumidifying passage is caused by any chance that the regenerated air leaks out. 11, even if condensed water is generated, the condensed water can be reliably received and drained to the tank 107 via the sub-tank 50 through the water passage hole 47. As a result, unintentional leakage of water from the dehumidifier can be reliably prevented. In addition, in this embodiment, the water receiver 45 is provided so as to extend over the entire lower part of the heat exchangers 67A and 67B. Therefore, even if condensed water leaks from the heat exchangers 67A and 67B due to secular change, Since it can receive in the part 45, it can prevent reliably that water leaks from a dehumidifier.

  Moreover, since it is set as the structure which positions the lower part of heat exchanger 67A, 67B in the water receiving part 45, while improving the workability | operativity at the time of an assembly, the arrangement | positioning position can be aimed at. Furthermore, since the water receiving portion 45 is integrally formed with the duct cover 42 that closes the duct portion 40 provided at the lower portion of the base 31, the number of parts can be reduced. Moreover, since it is possible to prevent the member that becomes the flow resistance of the sucked air from being located in the dehumidifying passage 11, particularly in the dehumidifying rotor arrangement portion 34, it is possible to prevent the dehumidifying efficiency from being lowered by taking measures against water leakage. it can.

  In addition, the dehumidifier of this invention is not limited to the structure of the said embodiment, A various change is possible.

  For example, in the above-described embodiment, the lower portions of the heat exchangers 67A and 67B are positioned by the water receiver 45, but the heat exchangers 67A and 67B may be dedicated portions that receive only condensed water without positioning. . In this case, the water receiving portion 45 may be provided only in the region located under the rotor cover 59. Moreover, in the said embodiment, although the water receiving part 45 was integrally molded in the duct cover 42 which obstruct | occludes the duct part 40, it is good also as a structure which arrange | positions the exclusive water receiving part 45 which consists of another body. Furthermore, in the embodiment, the pair of heat exchangers 67A and 67B are assembled in a stacked state. However, a single heat exchanger may be assembled, or three or more heat exchangers may be stacked and assembled. Also good.

It is the schematic which shows the dehumidifier which concerns on embodiment of this invention. It is a perspective view of a dehumidifier. It is a center longitudinal cross-sectional view of a dehumidifier. It is a disassembled perspective view of each component with respect to a base. (A), (B) is a perspective view which shows the structure of the duct part formed in the base. It is a perspective view which shows the assembly | attachment state of a heat exchanger. It is the perspective view which looked at FIG. 6 from the front side. It is a disassembled perspective view of an inner side heat exchanger. It is a disassembled perspective view of an outer side heat exchanger. It is a perspective view which shows 1 process of an assembly | attachment operation | work. It is a principal part cross-sectional perspective view of FIG. It is a disassembled perspective view which shows a dehumidifier and an accessory. It is a perspective view which shows the state which attached the accessory to the dehumidifier.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Casing 11 ... Dehumidification passage 12 ... Regeneration passage 13 ... Front cover 17 ... Rear cover 25 ... Top cover 31 ... Base 40 ... Duct part 42 ... Duct cover 45 ... Water receiving part 52 ... Dehumidification rotor 59 ... Rotor cover 66 ... Rotation Shaft 67A, 67B ... Heat exchanger 98 ... Heater 99 ... Heater cover 102 ... Regenerative air circulation fan 103 ... Fan case 105 ... Indoor air circulation fan 107 ... Tank

Claims (4)

A casing that divides the interior into a dehumidifying passage and a regeneration passage;
A dehumidification rotor disposed so as to be rotatable by a driving means around a rotation axis extending in a substantially horizontal direction across both the passages;
A rotor cover disposed at one end of the regeneration passage divided by the dehumidifying rotor;
A heat exchanger connected to the rotor cover, constituting a part of the regeneration passage, cooling the regeneration air flowing through the inside by air circulating outside and removing moisture contained in the regeneration air;
A heater disposed in the regeneration passage for heating the regeneration air and the dehumidifying rotor;
A regenerative air circulation fan that is disposed in the regeneration passage and circulates the regenerative air from the heater through a heat exchanger;
An indoor air circulation fan that is disposed in the dehumidification passage and sucks indoor air and circulates dry air dehumidified by the dehumidification rotor into the room;
In a dehumidifier equipped with
A dehumidifier having a water receiving portion for receiving condensed water condensed around the rotor cover so as to be positioned at least in a lower portion of the rotor cover.   The dehumidifier according to claim 1, wherein a lower portion of the heat exchanger is positioned by the water receiver.   The dehumidifier according to claim 1 or 2, wherein the water receiver is provided so as to cover the entire lower portion of the heat exchanger. The casing includes a base extending in a substantially vertical direction, a first cover for closing one horizontal surface of the base, and a second cover for closing the other horizontal surface of the base,
A duct portion, which is connected to the outlet of the heat exchanger and forms a part of the regeneration passage, is formed in a lower portion of the base so as to extend in a substantially horizontal direction, and the duct portion that closes the open end of the duct portion. The dehumidifier according to any one of claims 1 to 3, wherein the water receiving portion is formed integrally with a cover.

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