JP2019093378A - Air-conditioning device - Google Patents

Abstract

To provide an air-conditioning device that can smoothly move conditioned air from an air-conditioning unit to an air-blowing unit.SOLUTION: The air-conditioning device comprises an air-conditioning part for conditioning humidity of air. The air-conditioning part comprises a dehumidification rotor and a capacitor having multiple pipes made of synthetic resin arranged to oppose to one side of the dehumidification rotor and arranged in parallel, in which is provided comb-shaped members having multiple teeth parallel to one another which are inserted among the multiple pipes of the capacitor, where the comb-shaped members are attached to the capacitor from the opposite side of the one side opposing to the dehumidification rotor.SELECTED DRAWING: Figure 11

Description

  The present embodiment relates to an air conditioner.

  An air conditioning unit comprising: an air conditioning unit that regulates at least one of temperature, humidity, and cleanliness of air; and a blower unit for releasing the air regulated by the air conditioning unit; There has been proposed an air conditioner including a blower unit having a blower section for sucking and blowing out the adjusted air (adjusted air).

  By the way, in the air conditioning apparatus, there was a problem that the movement of the adjustment air from the air conditioning unit to the air blowing unit was not smooth.

JP, 2015-108497, A

  The present embodiment provides an air conditioner that can facilitate the movement of conditioned air from the air conditioning unit to the blower unit.

  According to one aspect of the present embodiment, the air conditioning unit is provided to regulate the humidity of the air, and the air conditioning unit is disposed to face the one side of the dehumidification rotor and the one side of the dehumidification rotor, and in parallel And a condenser having a plurality of synthetic resin pipes disposed in the housing, the comb-shaped member having a plurality of parallel teeth inserted between the plurality of pipes of the condenser, the comb-shaped member being the dehumidifying unit. An air conditioner is provided that is attached to the condenser from the opposite side of the surface facing the rotor.

  According to the present embodiment, an air conditioner is provided in which the movement of the conditioned air from the air conditioning unit to the blower unit is smooth.

It is the perspective view seen from the front side of the air conditioning apparatus of this Embodiment. It is the perspective view seen from the back side of the air conditioning apparatus of this Embodiment. It is a perspective view which shows the casing and support plate of a 1st ventilation part which concern on this Embodiment. It is a disassembled perspective view which shows the air conditioning apparatus which concerns on this Embodiment. It is a top view which shows the casing and support plate of a 1st ventilation part which concern on this Embodiment, and an air-flow guide member. It is a disassembled perspective view of a casing and an air flow guide member of the 1st ventilation part concerning this embodiment. It is a perspective view which shows the casing of the 1st ventilation part which concerns on this Embodiment, and the air flow guide member attached to this. It is a top view which shows the casing of the 1st ventilation part which concerns on this Embodiment, and the air flow guide member attached to this. It is a perspective view which shows the air flow guide member which concerns on this Embodiment. It is a fragmentary sectional view showing the air harmony unit concerning this embodiment. It is a figure which notches and shows a part of air conditioning unit which concerns on this Embodiment. It is a perspective view which shows the comb-shaped member which concerns on this Embodiment. It is the perspective view which looked at the blowing unit concerning this embodiment from the bottom side. It is a flowchart which shows an example of operation | movement which controls heating of the dehumidification rotor of the dehumidifier which concerns on this Embodiment. It is a flowchart which shows another example of operation | movement which controls heating of the dehumidification rotor of the dehumidifier which concerns on this Embodiment. It is a flowchart which shows another example of operation | movement which controls heating of the dehumidification rotor of the dehumidifier which concerns on this Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. In the description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

  In addition, the embodiments shown below exemplify devices and methods for embodying the technical idea, and do not specify the materials, shapes, structures, arrangements and the like of the components to the following ones. . This embodiment can be variously modified based on the recitation of the claims.

  Referring to FIGS. 1 and 2, an air conditioner according to the present embodiment is indicated generally by the reference numeral 10. The air conditioning apparatus 10 of the present embodiment includes an air conditioning unit 12 for adjusting room air, and a blower unit 14 for delivering the air (adjusted air) adjusted by the air conditioning unit 12 into the room.

  As shown in FIG. 4, the air conditioning unit 12 includes an air conditioning unit 22 that regulates at least one of the temperature, humidity, and cleanliness of the air, and the first suction port 44 with the conditioning air regulated by the air conditioning unit. And a first air blower 23 for discharging the air from the first air outlet 50. In the air conditioning unit 12, an air adjusting unit 22 and a first air blowing unit 23 are accommodated inside a box-shaped housing 20.

  As shown in FIG.1 and FIG.2, the ventilation unit 14 is provided with the 2nd ventilation part 24 which attracts | sucks and blows off the adjustment air adjusted with the air conditioning unit, and the holding frame 26 holding a 2nd ventilation part. ing.

  The second blower 24 includes a housing 28 and a rotatably driven blower fan 29 (see FIG. 2) housed inside the housing 28. The blower fan 29 may be, for example, a propeller fan or a sirocco fan or a cross flow fan (not shown). The housing 28 surrounds the radially outer side of the blower fan 29 at the side wall portion. That is, the wind tunnel is formed by the side wall portion of the housing 28, and there is an advantage that the straightness of the air flow generated by the blower fan 29 is improved. The second air blower 24 sucks the conditioned air released from the air conditioning unit 12 into the inside of the housing 28, and the conditioned air sucked into the housing 28 into the room outside the housing 28. And a second outlet 28b for blowing out. A spiral panel 31 is provided at the second air outlet 28b. The spiral panel 31 takes an air flow generated by the blower fan 29 as a spiral air flow, and the spiral air flow straightly advances while spirally swirling to allow the conditioned air discharged from the air conditioning unit 12 to reach further away. Has the advantage of being able to The second blower 24 is further rotatably supported (pivoted) by the holding frame 26 about a horizontal axis Lh (see FIG. 1). That is, the second air blower 24 is configured to be able to swing in the vertical direction.

  The blower unit 14 is rotatably supported around the vertical axis Lv (see FIGS. 1 and 2) with respect to the air conditioning unit 12. That is, the blower unit 14 is configured to swing in the left and right direction.

  The air conditioning unit 12 and the air blowing unit 14 are in a reference posture (a state shown in FIGS. 1 and 2 in which the air blowing unit 14 is directed to the front and the second air outlet 28b is directed upward). When it becomes a stationary posture, it is formed so that it may become an integral box shape which has continuity like having installed the ventilation unit 14 on the air conditioning unit 12. As shown in FIG. In the reference posture, the gap between the air conditioning unit 12 and the air blowing unit 14 is narrow, and there is no level difference between the air conditioning unit 12 and the air blowing unit 14 and the air conditioner unit 12 is flat and dust and dirt do not easily enter the air conditioning unit 12 .

  The air conditioning unit 12 has an air intake 30 on the back surface 20b of the housing 20, and an air delivery port 32 for delivering the air adjusted by the internal air conditioning unit 12 to the outside of the housing 20 (see FIG. 10). ) Is provided in the form of an opening on the upper surface (top surface) 20c.

  As shown in FIGS. 1 and 13, in the blower unit 14, an air vent 27 communicating in the vertical direction is formed in the bottom wall portion of the holding frame 26. The air vents 27 are a number of windows (gaps) formed almost all over the bottom wall. Even if the blowing unit 14 shakes its neck in any direction in the left-right direction, the vent 27 is the air of the air conditioning unit 12 so that the many vents 27 on the bottom wall correspond to the air delivery openings 32 of the air conditioning unit 12. It is formed in a wider range than the delivery port 32. The holding frame 26 of the blower unit 14 has side wall portions 26a and 26b on the left and right sides, and a rear wall portion 26c on the rear side. Therefore, the holding frame 26 is U-shaped in plan view by the left and right side wall portions 26a and 26b and the rear wall portion 26c, and the whole amount of air can be blown without releasing the adjustment air, so that sufficient dehumidification performance can be ensured. is there. Further, not only the adjustment air is taken in from the air vent 27 formed in the bottom wall portion, but also the outside air is taken in from the air vent 33 formed in the rear wall portion 26c. It is possible to secure enough. Further, a suction port is formed on the substantially arc-shaped bottom surface of the second blower 24 substantially over the entire surface. Regardless of the direction in which the second air blower 24 swings in the vertical direction, the substantially arc-shaped bottom surface and the vent 27 in the bottom wall maintain a constant distance.

  As shown in FIGS. 1 and 10, the air conditioning apparatus 10 of the present embodiment is provided with a guiding air passage 45 for guiding the conditioned air discharged from the air conditioning unit 12 to the second suction port 28a of the second blower 24. ing.

  The induction air passage 45 is provided on the downstream side of the air delivery port 32 of the air conditioning unit 12, and the opening 18 of the support plate 16 described later is the inflow side (inlet), and the bottom wall of the holding frame 26 of the blower unit 14 And a space surrounded by left and right side wall portions 26a and 26b of the holding frame 26 and a rear wall portion 26c. The holding frame 26 of the blower unit 14 is provided to cover the air delivery port 32 of the air conditioning unit 12, and the lower portion of the holding frame 26 is disposed to be close to the upper portion of the air conditioning unit 12. By configuring in this manner, the air conditioning apparatus 10 according to the present embodiment guides the conditioned air discharged from the air conditioning unit 12 to the second suction port 28 a of the second blower 24 via the induction air passage 45. It has become possible.

  As shown in FIG. 13, the blower unit 14 includes a stepping motor 35 as a drive source. The stepping motor 35 is a synchronous motor that operates in synchronization with pulse power. The use of the stepping motor 35 not only facilitates accurate control in the lateral direction of the air blowing, but also reduces the number of parts (that is, eliminates the need for the link mechanism conventionally required), and the compactness of the rotating mechanism. Has the effect of A control unit (not shown) provided in the blower unit 14 allows the rotational angle of the stepping motor 35 to be electrically settable. In other words, the control unit sets the angle of the lateral swing of the blower unit 14 to the user (use It can be changed according to the setting input by the operation of the person). Specifically, as shown in FIG. 13, the fixing plate 37 is disposed behind the air vent 27 of the bottom wall portion 24A. A stepping motor 35, a left and right swinging shaft 39, and an origin detection means 41 are fixed to the fixed plate 37. The left and right swing axis 39 is a left and right swing rotation axis. The origin detection means 41 comprises an IR (infrared) sensor (for example, a phototransistor or the like). The origin detection means 41 may be configured of a magnet and a magnetic sensor or the like. As shown in the figure, the blower unit 14 includes swinging guide portions 43a, 43b and 43c which are provided around the left and right swinging shafts 39 and around the left and right swinging shafts 39 and guide the left and right swings. Furthermore, legs 47a, 47b, 47c and 47d for supporting the blower unit 14 are provided around the left and right swinging shaft 39. According to such a configuration, since the left and right swings are guided along the swing guide portion, it is possible to prevent rattling at the time of the left and right swings.

  As shown in FIGS. 1 and 2, a support plate 16 is interposed between the blower unit 14 and the air conditioning unit 12. As shown in FIG. 3, a fixed gear 49 is disposed on the support plate 16 coaxially with the vertical axis Lv, which is the rotation center of the blower unit 14, and the air feed of the air conditioning unit 12 is carried out in front of the vertical axis Lv. An opening 18 corresponding to the outlet 32 is formed, and a circular guide slit 21 is formed around the rotation axis so as to surround the rear of the fixed gear 49. As shown in FIG. 13, swing guide portions 43a, 43b, 43c are formed downward from the blower unit 14, and the tip of one swing guide portion 43a is formed in a hook shape, and the opening is opened. A groove formed in the curved edge 18 a of the portion 18 is hooked. In addition, washers are provided at the tips of the other swing guides 43 b and 43 c so as not to slip out of the guide slit 21. Further, since the swing guides 43a, 43b, and 43c are configured to turn only in a certain range according to the maximum angle of the left and right swings, they are also used to limit the angle of the left and right swings.

  As shown in FIGS. 3 and 5, an arc-shaped guide rail 16 a is provided along the front of the opening 18. Further, as shown in FIG. 13, rollers (not shown) are attached to the tips of the legs 47 a, 47 b, 47 c, 47 d provided downward from the blower unit 14, and the plurality of legs 47 a, 47 b , 47c, 47d, the rollers of the leg portions 47c, 47d contact the guide rail 16a, and the roller travels on the guide rail 16a during the left and right swing operation. Further, a hole 49a is formed in the central portion of the fixed gear 49, and a shaft 39 for swinging the left and right of the blower unit 14 is attached to the hole 49a. Further, on the upper surface of the support plate 16, a convex light shielding plate 57 for shielding the origin detection means (IR sensor) 41 is formed. When light is blocked by the light shielding plate 57, the origin detection means (IR sensor) 41 detects the origin of the left and right swing. In the present invention, the origin of the left and right swing indicates the reference posture in which the blower unit 14 faces the front.

  As described above, in the air conditioner 10 of the present embodiment, the inflow side opening (reference numeral 18) of the induction air passage 45 is the air outlet 32 of the air conditioning unit 12 (the first blowing portion of the first blowing portion 23). It is provided downstream of the outlet 50).

  As shown in FIGS. 6 and 7, in the air conditioner 10 of the present embodiment, an air flow guiding member 52 for guiding air corresponding to the shape of the inflow side opening 18 is provided in the first outlet 50. . The air flow guide member 52 cooperates with the casing 40 of the first air blower 23 to form a first air outlet 50. The first air outlet 50 is released toward (directed to) the inflow side opening 18 of the induction air passage 45, and in the illustrated example, the first air outlet 50 corresponds to the shape of the inflow side opening 18 It has an arched shape. The arcuate shape may be formed of two sectors which are divided into two at the center between both ends of the curved and extending edge portion 56. Alternatively, the bow shape may be provided between both ends of the edge portion 56. It may be formed of a plurality of rectangles having different shapes.

  The illustrated casing 40 of the first air blower 23 has a pair of left and right side plates 50a, 50b opposite to each other and a side plate 50c connected to the left and right side plates 50a, 50b. The three side plates 50a, 50b, 50c Are formed to form a U-shape. The airflow guiding member 52 includes three side plates consisting of a pair of left and right side plates 52a, 52b fitted between a pair of side plates 50a, 50b of the casing, and one side plate 52c connected to the left and right side plates 52a, 52b. It has a top plate 52d connected to the side plates 52a, 52b, 52c. The side plates 50a and 50b of the casing are provided with two rectangular locking recesses 51 respectively facing each other, and the both side plates 52a and 52b of the air flow guiding member 52 are two locking members elastically deformable which are mutually opposite A protrusion 53 is provided. The air flow guide member 52 is fitted to the casing 40 by the engagement of the locking projection 53 with the locking recess 51. The air flow guide member 52 has an arc-shaped (arcuate) edge portion 56 corresponding to the inner edge of the arc-shaped guide rail 16 a of the support member 16.

  The air flow guide member 52 is formed to guide air by a step-free guide surface. As shown in FIG. 9, the air flow guide member 52 is provided with an arc-shaped (arcuate) edge portion 56 on the downstream side of the air flow, and has a straight edge portion 52e on the upstream side of the air flow. . A smooth curved guide surface 68 is provided between the arc-shaped edge portion 56 and the linear edge portion 52e. Further, one side plate 52a of the air flow guiding member 52 has a sloped surface portion 58 curved in a concave shape in which the lower end portion is in contact with the step 61 of the casing 40 and connected to the corner portion 58a of the projecting portion described later. (See FIG. 10). The air flow guide member 52 is configured to minimize the formation of a step at the mating portion with the casing, enabling the air flow to flow smoothly and preventing the generation of noise due to the air flow hitting the step. .

  As shown in FIG. 10, the first blower 23 includes a multi-blade centrifugal fan 38 and a casing 40 rotatably supporting the multi-blade centrifugal fan 38, and the multi-blade centrifugal fan 38 is rotated by a motor (not shown). By doing this, the multi-blade centrifugal fan 38 and the casing 40 are configured to jointly generate an air flow.

  In the air flow guide member 52, at least a part of a guide surface located on the downstream side in the rotational direction of the multi-blade centrifugal fan 38, an inclined surface portion 58 overlapping the tangent L1 contacting the outer peripheral edge of the multi-blade centrifugal fan is formed. As shown in FIG. 10, since the sloped surface portion 58 overlaps the tangent L1, the sloped surface portion 58 is the air sent out along the tangent L1 forward (indicated by the arrow 63) by the multi-blade centrifugal fan 38 in the rotational direction. And flow along a nearly parallel shape. This configuration reduces the energy loss or pressure loss of the fluid. Also, from this, it is possible to make the flow of the air blown out from the first blowout port 50 smoother with less disturbance.

  As shown in FIGS. 9 and 10, the air flow guide member 52 has a protrusion 70 at the lower position of the inclined surface 58, and is configured to receive the air flow from the multi-blade centrifugal fan on the side surface of the protrusion 70. ing. The projecting portion 70 is in contact with the tip end surface of the projecting portion 72 projecting from the one side plate 50 a of the casing 40 at the lower position of the inclined surface portion 58. According to this, the side surface of the projecting portion 70 becomes the wind receiving surface portion 65 which receives the air flow sent out from the multi-blade centrifugal fan 38, and there is no gap in the air receiving surface portion 65 along the air flow feeding direction. Thus, it is possible to prevent the leakage of the dehumidified air through the gap and the generation of pressure loss, the generation of noise, etc. when there is a gap along the air flow feeding direction. In other words, at the seam 67 where the projecting portion 72 of the casing 40 and the projecting portion 70 are in contact, there is almost no gap, or even if there is a gap, it is formed orthogonal to the air flow feeding direction. Can be minimized.

  As shown in FIGS. 6 and 10, at the first air outlet 50, there are provided flow straightening piece portions 62 provided on opposite sides of the side face of the projecting portion 70 of the air flow guiding member 52 at intervals. The straightening piece portion 62 can be disposed at any position between the side plates 50a and 50b of the first outlet 50. In the illustrated example, the straightening piece portion 62 is connected to the side plates 50a and 50b from one side plate 50a. And a position near the other side plate 50b, which is about 2/3 of the distance between them. The rectifying piece portion 62 is disposed so as to substantially overlap with a tangent L2 (different from the tangent L1) of the multi-blade centrifugal fan 38. Preferably, the straightening piece portion 62 is gently curved.

  At the first outlet 50, the air flow generated by the rotation of the multi-blade centrifugal fan 38 tends to be blown toward the side surface (wind receiving surface 65) of the protrusion 70 on the downstream side in the rotational direction, A pressure difference occurs in the space on the left side in the drawing and the space on the right side in the blowout port 50. The flow straightening portion 62 guides the air flow flowing in the space on the right side of the first outlet 50 in the direction parallel to the tangent L2 of the multi-blade centrifugal fan 38 (the direction indicated by the arrow 69 in the figure) Suppress the occurrence of That is, the flow control piece portion 62 prevents the generation of noise by preventing the fluttering phenomenon (turbulence) of the wind generated due to the pressure difference. Also, energy loss or pressure loss of the fluid is reduced.

  In the air conditioning apparatus of the present embodiment, the air conditioning unit 12 has an air conditioning unit 22 having a function of regulating the humidity of the air. That is, the dehumidifier (with a circulator) is illustrated as one form of an air conditioning apparatus.

  Here, the basic structure of the desiccant type dehumidifier will be described. For example, as shown in FIG. 4, the multi-blade centrifugal includes a dehumidifying rotor 36, a condenser (heat exchanger) 34 described later, and a heater 42. It has a first air blower 23 composed of a fan 38 and a casing 40. A temperature sensor 43 is attached to the heater 42. The temperature sensor 43 is made of, for example, bimetal. As the operation of the dehumidifier, the first air blower 23 is operated to suck air in the room through the air intake port 30 of the housing 20, pass through the dehumidification rotor 36, and adsorb moisture in the air. Thus, the air is dehumidified in the housing 20. The moisture adsorbed by the dehumidifying rotor 36 is converted to steam by heating by the heater 42.

  As shown in FIG. 11, the water vapor generated by the heating of the heater 42 is introduced into a large number of synthetic resin pipes 34a constituting the condenser 34, cooled by the air present in the housing 20, and condensed to form water. Become. This water flows through the subtank 46A disposed in the housing 20, flows down to the main tank 46B disposed at the bottom of the housing 20 and in communication with the subtank 46A, and is stored in the main tank.

  The air conditioning unit 22 includes a condenser 34 having a large number of synthetic resin pipes 34a arranged in parallel, and is provided with a comb-shaped member 72 having a large number of mutually parallel teeth inserted between the large number of pipes of the condenser. It is done. The teeth 74 (see FIG. 12) of the comb-shaped member 72 are located between the pipes 34a of the condenser 34 to correct deformation during molding of the pipe 34a and to prevent deformation over time during use. Thereby, the deterioration of the dehumidifying performance of the condenser 34 is prevented.

  Also, as shown in FIG. 12, each tooth 74 of the comb member 72 has a tapered tip 74a. This can facilitate insertion of the comb member 72 between the multiple pipes 34 a of the condenser 34. Also, this allows the teeth 74 of the comb member 72 to be inserted more deeply, and the comb member 72 can be reliably held by the condenser 34.

  As shown in FIG. 11, the air conditioning unit 12 includes a temperature and humidity sensor 48 that detects temperature and humidity. The air conditioning unit 12 includes a control unit 71 (see FIG. 4) that controls the heating of the dehumidifying rotor 36 by the heater 42 based on the humidity detected by the temperature and humidity sensor 48.

  Specifically, in the air conditioning unit 12, as shown in FIG. 14, the temperature and humidity are detected by the temperature and humidity sensor 48 (step S1), and then the indoor humidity detected by the temperature and humidity sensor 48. It is determined whether (relative humidity) is less than a predetermined threshold (for example, 30%) (step S2), and if the humidity (relative humidity) is less than the predetermined threshold, the heater 42 is switched off ( Step S3), it controls to stop the heating of the dehumidification rotor 36. On the other hand, when the humidity (relative humidity) is equal to or higher than a predetermined threshold value, detection of temperature and humidity by the temperature and humidity sensor 48 is repeated. The predetermined threshold value for switching the heater 42 to OFF is set to, for example, an arbitrary value in the humidity range of 20% to 40%. When the relative humidity detected by the temperature and humidity sensor 48 exceeds another threshold (for example, 35%) higher than the above threshold after switching the heater 42 to OFF, the heater 42 is switched to ON and the dehumidifying rotor 36 Control to resume heating. The threshold value for this return is set to any value higher than the threshold value for switching the heater 42 off in the 25% to 45% humidity range. In addition, threshold values of relative humidity of a plurality of stages are set in advance, and it is determined whether the humidity (relative humidity) detected by the temperature and humidity sensor 48 is less than the highest threshold among the plurality of stages. In addition, the output of the heater 42 is further reduced, and the output of the heater 42 is reduced in a plurality of stages. Then, it may be determined whether it is less than the lowest threshold among the plurality of stages, and in such a case, the heater 42 may be controlled to be switched off. Thus, it is also preferable to reduce the output of the heater 42 in multiple stages and finally switch the heater 42 OFF. The air conditioning unit 12 prevents the overheating of the dehumidification rotor 36 by controlling the heater 42 described above, and heats the synthetic resin components that constitute peripheral devices (for example, the condenser 34) accompanying the overheating of the dehumidification rotor 36. It is possible to prevent the occurrence of melting, fire and the like.

  Further, the air conditioning unit 12 controls the heating of the dehumidifying rotor 36 by the heater 42 based on the temperature detected by the temperature and humidity sensor 48 in the control unit 71.

  Specifically, as shown in FIG. 15, the temperature / humidity sensor 48 detects temperature / humidity (step S10), and then the temperature detected by the temperature / humidity sensor 48 is a predetermined threshold (for example, 38.degree. C.). Is determined (step S11). If the temperature exceeds a predetermined threshold, the heater 42 is switched off (step S12), and control is made to stop the heating of the dehumidifying rotor 36. On the other hand, if the temperature is equal to or less than the predetermined threshold value, detection of the temperature and humidity by the temperature and humidity sensor 48 is repeated. The predetermined threshold value for switching the heater 42 to OFF is set to, for example, an arbitrary value within a temperature range of 34 ° C to 40 ° C. When the temperature detected by the temperature and humidity sensor 48 falls below another threshold (for example, 36 ° C.) lower than the above threshold after switching the heater 42 to OFF, the heater 42 is switched to ON and the dehumidifying rotor 36 Control to resume heating. The threshold value for this return is set to an arbitrary value lower than the threshold value for switching the heater 42 off in the temperature range of 32 ° C. to 38 ° C. Further, based on the temperature detected by the temperature and humidity sensor 48, the output of the heater 42 may be reduced in multiple stages and the heater 42 may be switched off at the end.

  The air conditioning unit 12 preferably controls the heating of the dehumidifying rotor 36 by the heater 42 based on the absolute humidity detected by the temperature and humidity sensor 48 in the control unit 71.

Specifically, as shown in FIG. 16, the temperature / humidity sensor 48 detects the temperature / humidity (step S20), and then the absolute humidity detected by the temperature / humidity sensor 48 is a predetermined first threshold (for example, It is determined whether it is less than 9.2 g / m ³ ) (step S21). If the absolute humidity is less than the first threshold, the output of the heater 42 is reduced, and then the second threshold and the third threshold If ... is set, the absolute humidity is compared with each of the threshold values, and if it is less than the threshold value, the output of the heater 42 is sequentially reduced, and then a predetermined final threshold value (for example, 3.). It is determined whether it is less than 0 g / m ³ ) (step S22). If the absolute humidity is less than the final threshold value, the heater 42 is switched off (step S23) to stop the heating of the dehumidifying rotor 36 Control. Note that after the heater 42 is switched off, the heater 42 is switched on to set a recovery threshold value for resuming (restoring) the heating of the dehumidifying rotor 36.

  The air conditioning unit 12 measures the temperature of the heater 42 directly by the temperature sensor (bimetal) 43 (see FIG. 4) attached to the outside of the heater 42 in addition to the control of the heater 42 by the temperature and humidity sensor 48 described above. When the heating state of is detected, the heater 42 is switched to OFF. That is, the air conditioning unit 12 prevents the heating of the heater 42 by the temperature / humidity sensor 48 and the temperature sensor 43 attached to the heater 42 and takes double safety measures.

  The air conditioning unit 12 includes a weight sensor that detects the amount of water flowing from the condenser 34 to the sub tank 46A and the main tank 46B, and the dehumidifying rotor 36 with the heater 42 based on the amount of water detected by the weight sensor. You may control the heating of. That is, when the amount of water flowing from the condenser 34 and flowing into the sub tank 46A and the main tank 46B is less than a predetermined small amount, the heater 42 is turned off or the output of the heater 42 is reduced.

[Other Embodiments]
Although the foregoing describes the embodiment, the description and the drawings, which form a part of this disclosure, are illustrative and should not be construed as limiting. Various alternative embodiments, examples and operation techniques will be apparent to those skilled in the art from this disclosure.

  For example, the air conditioning apparatus according to the present embodiment may include the air conditioning unit 22 for adjusting at least one of the temperature, the humidity, and the cleanliness of the air in the air conditioning unit 12, in addition to the illustrated dehumidifier. In addition, a humidifier, an air cleaner, a heater, or a device combining two or more of them may be used.

The air conditioner according to the present embodiment can be used for indoor air conditioning.
For example, the dehumidifier can be used to dry clothes, dried fish, paint, etc., or as a humidifier can be used to adjust the humidity of room air.

DESCRIPTION OF SYMBOLS 10 Air conditioning apparatus 12 Air conditioning unit 14 Air blower unit 16 Support member 18 Inflow side opening 20 Housing 22 Air adjustment part 23 1st air blower 24 2nd air blower 25 Dehumidifier 28 Housing 28a 2nd suction port 28b 2nd blower outlet Reference Signs List 30 air intake 32 air delivery port 34 condenser 34a pipe 36 dehumidifying rotor 38 multi-blade centrifugal fan 40 casing 42 heater 44 first suction port 45 induction air path 50 first outlet 52 air flow guiding member 54 flow path 56 peripheral edge portion 62 Rectifying piece

Claims (2)

It has an air conditioning unit that regulates the humidity of the air.
The air conditioning unit includes a dehumidifying rotor, and a condenser having a large number of synthetic resin pipes disposed so as to face one surface of the dehumidifying rotor and arranged in parallel.
An air conditioner provided with a comb member having a number of mutually parallel teeth inserted between the multiple pipes of the condenser, wherein the comb member is attached to the condenser from the opposite side of the surface facing the dehumidifying rotor apparatus. The air conditioner according to claim 1, wherein each tooth of the comb-shaped member has a tapered tip.