JP5621535B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner including a humidification unit installed outdoors.

  Conventionally, there is an air conditioner that can supply humidified air from a humidifying unit installed outdoors to an indoor unit installed indoors. Further, the humidifying unit provided in such an air conditioner includes a desorption rotor capable of desorbing moisture, a heater for heating air passing through the desorption rotor to desorb moisture from the desorption rotor, and heating by the heater. And a fan for flowing the generated air to the desorption rotor.

  Here, since the temperature of the air passing through the desorption rotor decreases from the time when it is heated by the heater until it reaches the desorption rotor, the amount of water desorbed by the desorption rotor is reduced by the amount of the temperature decrease. In this case, the amount of moisture desorbed by the desorption rotor increases by raising the temperature of the heater, but there is a problem that the desorption efficiency of moisture from the desorption rotor is deteriorated.

  Therefore, for example, in a humidification unit provided in an air conditioner disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2010-144972), air heated by a heating device (corresponding to a heater) 510 is used as a humidification rotor (desorption rotor). Equivalent) In order to distribute equally to each part of 520, the humidification side air distribution part 512 is arranged between exothermic body 511 which heater 150 has, and humidification rotor 520 (refer to Drawing 14 and Drawing 15). In this air conditioner, the humidifying rotor 520 is provided by providing the humidifying air distribution unit 512 to increase the portion of the humidifying rotor 520 through which the air heated by the heating device 510 passes and to increase the moisture desorbed from the humidifying rotor 520. Improves moisture desorption performance.

  By the way, the humidification side air distribution part 512 currently disclosed by patent document 1 is a punching board 512a which is substantially fan shape in planar view, and is provided with the several through-hole as FIG.14 and FIG.15 shows. And an inner peripheral wall 512b erected on the inner peripheral edge of the punching plate 512a and an outer peripheral wall 512c erected on the outer peripheral edge of the punching plate 512a. As described above, in the conventional technology, in order to improve the moisture desorption performance of the desorption rotor, a component having a complicated configuration is required.

  Accordingly, an object of the present invention is to provide an air conditioner that can improve the moisture desorption performance of a desorption rotor with a simple configuration.

An air conditioner according to a first aspect of the present invention includes an indoor unit, an outdoor unit, a humidification unit, and a humidified air supply path. The indoor unit is installed indoors. The outdoor unit is installed outdoors. The humidification unit is installed outdoors. The humidification unit has a desorption rotor, a heater, and a fan. The desorption rotor can adsorb moisture contained in the outdoor air, and desorbs moisture when heated. The heater heats air passing through the desorption rotor to desorb moisture from the desorption rotor. The fan generates an air flow that causes air heated by the heater to flow to the desorption rotor. The humidified air supply path connects the humidifying unit and the indoor unit. Further, the humidified air supply path can supply air containing moisture desorbed from the desorption rotor to the indoor unit. Furthermore, the heater has a heater body as a heating element and a wind direction adjusting plate. Wind direction adjusting plate is positioned in the air flow downstream of Ri by heater body. The wind direction adjusting plate includes an intersecting portion and an inclined portion. The intersecting portion extends in a direction intersecting the air flow direction. The inclined portion extends in the air flow direction from the end of the intersecting portion. In addition, the inclined portion includes an inclined surface that restricts the air flow so that the air that has passed through the heater body is directed toward the desorption rotor.

  Conventionally, in order to improve the moisture desorption performance of the desorption rotor, a portion of the desorption rotor through which the air heated by the heater passes is increased by providing an air distribution portion having a complicated shape on the downstream side of the heater. . However, in this conventional technique, in order to improve the moisture desorption performance of the desorption rotor, components having a complicated configuration are required.

  Therefore, in the air conditioner according to the first aspect of the present invention, the air flow through the heater body is directed toward the desorption rotor side by the inclined surface of the wind direction adjusting plate located downstream of the heater body. The air passing through the heater body is regulated. In this air conditioner, the air passing through the heater body is regulated by the inclined surface of the wind direction adjusting plate so as to be directed toward the desorption rotor side. The part through which air passes can be increased.

  Accordingly, the moisture desorption performance of the desorption rotor can be improved with a wind direction adjusting plate having a simple configuration.

  The air conditioner according to a second aspect of the present invention is the air conditioner according to the first aspect, wherein the wind direction adjusting plate is provided with a slit-like opening that is long in the longitudinal direction of the wind direction adjusting plate. Moreover, the inclined surface is arrange | positioned along the edge of the longitudinal direction of opening. In this air conditioner, since the opening is formed in the air direction adjusting plate, the air from the passage through the heater body to the desorption rotor is compared with the case where the opening is not formed in the air direction adjusting plate. The number of channels can be increased.

  Thereby, the part through which the air which passed the heater main body in a desorption rotor can be increased.

  The air conditioner according to a third aspect of the present invention is the air conditioner according to the first aspect or the second aspect, wherein the heater is a separate member from the wind direction adjusting plate, and further includes a heater support frame that supports the heater body. Have. In this air conditioner, since the wind direction adjusting plate and the heater support frame are formed separately, for example, compared to the case where the air direction adjusting plate and the heater support frame are integrally formed, the air direction of a complicated shape is used. The adjustment plate can be easily formed.

  The air conditioner according to a fourth aspect of the present invention is the air conditioner according to the first aspect or the second aspect, wherein the wind direction adjusting plate is a part of a heater support frame that supports the heater body. In this air conditioner, since the wind direction adjusting plate is a part of the heater support frame, for example, compared to the case where the wind direction adjusting plate and the heater support frame are separate, the air direction adjusting plate is installed in the heater at the time of heater assembly. The work of assembling to the support frame can be omitted.

  An air conditioner according to a fifth aspect of the present invention is the air conditioner according to any one of the first to fourth aspects, wherein the heater includes a flow path forming portion that forms an air flow path from the heater body toward the desorption rotor. Have. The wind direction adjusting plate is disposed in a region near the heater body in the air flow path. In this air conditioner, since the wind direction adjusting plate is disposed in a region in the vicinity of the heater body in the air flow path from the heater body to the desorption rotor, it is possible to regulate high-temperature air immediately after coming out of the heater body. .

  An air conditioner according to a sixth aspect of the present invention is the air conditioner according to any one of the first to fourth aspects, wherein the heater includes a flow path forming portion that constitutes an air flow path from the heater body toward the desorption rotor. Have. The wind direction adjusting plate is arranged in a region away from the heater body in the air flow path. In this air conditioner, the air direction adjusting plate is disposed in a region away from the heater main body in the air flow path from the heater main body toward the desorption rotor, so that air at a position away from the heater main body can be regulated.

  In the air conditioner according to the first aspect of the present invention, the moisture desorption performance of the desorption rotor can be improved with a wind direction adjusting plate having a simple configuration.

  In the air conditioner according to the second aspect of the present invention, it is possible to increase the portion through which the air flows through the heater body in the desorption rotor.

  In the air conditioner according to the third aspect of the present invention, it is possible to easily form a wind direction adjusting plate having a complicated shape.

  In the air conditioner according to the fourth aspect of the present invention, the work of assembling the air direction adjusting plate to the heater support frame can be omitted at the time of assembling the heater.

  In the air conditioner according to the fifth aspect of the present invention, high-temperature air immediately after coming out of the heater body can be regulated.

  In the air conditioner according to the sixth aspect of the present invention, air at a position away from the heater body can be regulated.

The front view of the air conditioner which concerns on one Embodiment of this invention. The figure for demonstrating the flow of the air in a humidification unit and an indoor unit (The 2nd air intake port for adsorption | suction is abbreviate | omitted). The disassembled perspective view of a humidification unit. The schematic of the heater seen from the humidification rotor side. The partial perspective view of a heater. Schematic of a humidification rotor and a heater. Schematic of a heater support frame. The schematic perspective view of a wind direction adjustment board. (A) The figure which looked at the wind direction adjustment board from the arrow X direction of FIG. 8, (b) Sectional drawing of a wind direction adjustment board (equivalent to the bb cross section of Fig.9 (a)). The figure for demonstrating the positional relationship of a wind direction adjustment board and a heater support frame. The schematic diagram of the heater in modification (A). The schematic diagram of the heater in a modification (B). The schematic diagram of the heater support frame in a modification (B). Schematic of a conventional heater. Schematic of a conventional heater.

  Hereinafter, an air conditioner 10 according to an embodiment of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) Configuration of Air Conditioner As shown in FIG. 1, the air conditioner 10 is a pair-type air in which one outdoor unit 11 and one indoor unit 12 are connected in parallel by a refrigerant pipe. It is a harmony machine. The air conditioner 10 can perform operations such as cooling operation, heating operation, dehumidification operation, humidification operation, air supply operation, and exhaust operation. The air conditioner of the present embodiment is a pair type air conditioner, but is not limited thereto, and is a multi-type air conditioner in which a plurality of indoor units are connected to one outdoor unit. May be.

  As shown in FIG. 2, the outdoor unit 11 includes an outdoor air conditioning unit 20 that houses an outdoor heat exchanger 24, an outdoor fan 29, and the like, and a humidification unit 50. An indoor heat exchanger 13 and an indoor fan 14 are accommodated inside the indoor unit 12. An intake / exhaust duct 15 is provided between the humidifying unit 50 and the indoor unit 12 so that the internal space of the humidifying unit 50 and the internal space of the indoor unit 12 can communicate with each other.

  Below, the detail of the indoor unit 12 and the outdoor unit 11 with which the air conditioner 10 is provided is demonstrated.

(2) Configuration of indoor unit The indoor unit 12 is a wall-mounted indoor unit installed on a wall surface of a room. The indoor unit 12 includes an indoor unit casing 16, an indoor heat exchanger 13, and an indoor fan 14, and the indoor heat exchanger 13 and the indoor fan 14 are accommodated in the indoor unit casing 16.

  The indoor heat exchanger 13 includes a heat transfer tube that is bent back and forth at both ends in the longitudinal direction and a plurality of fins that are inserted through the heat transfer tube, and performs heat exchange between the air that contacts the heat transfer tube.

  The indoor fan 14 is a cross flow fan, and generates an air flow in a direction intersecting with the rotation axis by being driven to rotate. The indoor fan 14 sucks indoor air into the indoor unit 12 and blows out air after heat exchange with the indoor heat exchanger 13 into the room.

  In the indoor unit 12, the indoor fan 14 is rotated and an air flow is generated, and is downstream of the air intake port 16 a provided in the upper part of the indoor unit 12, and the indoor heat One end of the intake / exhaust duct 15 is disposed in the space upstream of the exchanger 13.

(3) Configuration of Outdoor Unit As shown in FIGS. 1 and 2, the outdoor unit 11 includes a lower outdoor air conditioning unit 20 and an upper humidification unit 50. For this reason, in this outdoor unit 11, the power supply of the outdoor air conditioning unit 20 and the humidification unit 50 can be unified.

(3-1) Configuration of Outdoor Air Conditioning Unit In the outdoor air conditioning unit 20, as shown in FIG. 2, a compressor 21, a four-way switching valve 22 connected to the discharge side of the compressor 21, and the compressor 21. The accumulator 23 connected to the suction side of the air, the outdoor heat exchanger 24 connected to the four-way switching valve 22, and the outdoor expansion valve 25 connected to the outdoor heat exchanger 24 are accommodated. The outdoor expansion valve 25 is connected to a liquid refrigerant pipe via a filter 26 and a liquid closing valve 27, and is connected to one end of the indoor heat exchanger 13 via this liquid refrigerant pipe. The four-way switching valve 22 is connected to a gas refrigerant pipe through a gas closing valve 28, and is connected to the other end of the indoor heat exchanger 13 through the gas refrigerant pipe.

(3-2) Configuration of Humidification Unit FIG. 3 is an exploded perspective view of the humidification unit 50.

  As shown in FIGS. 1, 2 and 3, the humidification unit 50 includes a humidification unit casing 51, a humidification rotor (corresponding to a desorption rotor) 52, a heater 60, an adsorption blower 55, and a flow path switching device. 53 and an intake / exhaust fan 54. The humidification unit 50 can exhaust the air taken in from the room to the outside or supply the outdoor air taken in from the room to the room. In addition, outdoor air can be humidified and supplied to the room.

(3-2-1) Humidification Unit Casing The humidification unit casing 51 houses a humidification rotor 52, a heater 60, an intake / exhaust fan 54, a flow path switching device 53, an adsorption blower 55, and the like.

  As shown in FIGS. 1 and 3, an adsorption air blowing port 51 a and a first adsorption air intake port 51 b made up of a plurality of slit-like openings are provided side by side on the front surface (front surface) of the humidifying unit casing 51. It has been. The first adsorption air intake port 51 b is an opening through which air taken in from the outdoor in order to cause the humidification rotor 52 to adsorb moisture. The adsorption air outlet 51 a is an opening for discharging the air after the moisture has been adsorbed by the humidification rotor 52 through the moisture absorption channel 58 a to the outside of the humidification unit casing 51. In addition, on the back surface of the humidifying unit casing 51, there are provided a second adsorption air intake port 51c and intake / exhaust port 51d formed of a plurality of slit-shaped openings (see FIGS. 2 and 3). Similarly to the first adsorption air intake port 51b, the second adsorption air intake port 51c is an opening through which air taken in from the outdoor in order to adsorb moisture to the humidification rotor 52 passes. The intake / exhaust port 51d is an opening for taking outdoor air into the humidification flow path 58b during the humidification operation or the air supply operation. When outdoor air flows into the humidification flow path 58 b, it passes through a portion of the humidification rotor 52, is heated by the heater 60, then passes through another portion of the humidification rotor 52, and toward the intake / exhaust fan 54. Flowing. Further, during the exhaust operation, air taken from the indoor unit 12 flows into the humidification flow path 58b in the humidification unit 50 and is exhausted to the outside through the intake / exhaust port 51d.

(3-2-2) Humidification rotor The humidification rotor 52 is a ceramic rotor having a honeycomb structure and has a substantially disk-shaped outer shape. The humidifying rotor 52 is rotatably provided and is driven to rotate by a rotor driving motor. Further, the main part of the humidification rotor 52 is fired from an adsorbent such as zeolite. Adsorbents such as zeolite have the property of adsorbing moisture in the contacting air and desorbing the adsorbed moisture by heating. In this embodiment, zeolite is used as the adsorbent, but silica gel, alumina, or the like can also be used as the adsorbent. Thus, the humidification rotor 52 can be reduced in size because the humidification rotor 52 is substantially disk shape.

(3-2-3) Heater The heater 60 is located above the humidification rotor 52 and is disposed to face the humidification rotor 52. The heater 60 heats the air sent to the humidification rotor 52 in order to desorb moisture from the humidification rotor 52. When the air heated by the heater 60 is sent to the humidification rotor 52, the humidification rotor 52 is heated.

  As shown in FIGS. 4, 5, and 6, the heater 60 mainly includes an outer shell portion 61, a flow path forming portion 62, a main body 63, and a wind direction adjusting plate 64.

  The outer shell portion 61 has a semicircular base portion 61a and an outer wall portion 61b erected from an edge portion of the base portion 61a. The flow passage forming portion 62 to which the main body 63 and the wind direction adjusting plate 64 are fixed is provided. It can be accommodated inside. The base 61a is provided with screw holes (not shown) for fixing the flow path forming part 62, the main body 63, and the wind direction adjusting plate 64 to the outer shell part 61 with screws 65a, 65b, 65c. .

  The flow path forming part 62 has a substantially fan-shaped plate part 62a and a side wall part 62b erected from the edge of the plate part 62a. Further, the plate portion 62a and the side wall portion 62b are provided with through holes (not shown) at positions corresponding to claw portions (not shown) provided on a heater support frame 63b described later. Further, the plate part 62 a and the side wall part 62 b are a part of the humidification flow path 58 b, and constitute a heated air flow path 66 that blows out from the main body 63 and flows air toward the humidification rotor 52. The heating air flow path 66 constituted by the plate portion 62a and the side wall portion 62b has a substantially fan shape in plan view, and is located on the downstream side of the air flow from an outlet side opening 63bc described later (FIG. 6). reference).

  The main body 63 includes a plurality of heating wires (corresponding to a heater main body) 63a as heating elements, and a heater support frame 63b that houses the heating wires 63a. The top surface 63ba of the heater support frame 63b is provided with a plurality of claw portions (not shown). The heater support frame 63 b is fixed to the flow path forming portion 62 by locking these claw portions to the peripheral edge portion of the through hole provided in the flow path forming portion 62. The heater support frame 63b is provided with an inlet side opening 63bb and an outlet side opening 63bc opposite to the inlet side opening 63bb (see FIGS. 5 and 7). The air that has entered the heater support frame 63b through the inlet side opening 63bb is heated by the heating wire 63a and blown out of the heater support frame 63b through the outlet side opening 63bc. In the present embodiment, the heater support frame 63b and the wind direction adjusting plate 64 are separate components.

  The air direction adjusting plate 64 is disposed on the downstream side of the air flow with respect to the heating wire 63 a and in a region near the main body 63 in the heated air channel 66. Specifically, when the heated air flow channel 66 is divided into two parts, that is, a front part and a rear part on the downstream side of the air flow from the front part so as to have substantially the same volume, the wind direction of the present embodiment. More than half of the adjustment plate 64 is arranged at the front. 8 and 9, the wind direction adjusting plate 64 is a plate-like member having a substantially L-shaped cross section, and includes a first plate portion 67 having a substantially rectangular shape, and a first plate portion. And a second plate portion 68 extending in a direction intersecting the first plate portion 67 from one long side of 67.

  A screw hole 67 a for fixing the wind direction adjusting plate 64 to the flow path forming portion 62 and the outer shell portion 61 is provided at one end portion of the first plate portion 67.

  The second plate portion 68 includes an intersecting portion 68a, a first inclined portion 68b, and a second inclined portion 68c. The intersecting portion 68 a has a substantially rectangular shape, and is arranged so as to intersect with the air flow flowing through the heated air flow channel 66 in a state where the air direction adjusting plate 64 is fixed to the flow channel forming portion 62. Specifically, as shown in FIG. 10, the intersecting portion 68a includes a first virtual surface P2 that is a plane including the surface 68ac of the intersecting portion 68a on the heater support frame 63b side, and an outlet side opening 63bc of the heater support frame 63b. The second imaginary plane P1, which is a plane including the opening surface, is arranged in the heated air flow channel 66 so as to intersect at a predetermined angle θ. In the present embodiment, the predetermined angle θ is 15 degrees, but the angle of the predetermined angle θ is not limited to this, and the intersecting portion 68a is positioned so as to intersect the flow of air flowing through the humidified air flow channel 66. Any angle can be used. The predetermined angle θ is preferably in the range of 10 degrees to 20 degrees. Further, a plurality (four in this embodiment) of slit-like openings 68aa and 68ab along the longitudinal direction are formed in the intersecting portion 68a. In the following, for convenience of explanation, two openings provided in a portion close to the first plate portion 67 among openings provided in the intersecting portion 68a are referred to as a first opening 68aa, which is more than the first opening 68aa. Two openings provided in a portion far from the first plate portion 67 are referred to as a second opening 68ab.

  The 1st inclination part 68b and the 2nd inclination part 68c regulate the air which flowed from the exit side opening 63bc so that the air which passed the main body 63 goes to the humidification rotor 52 side. The first inclined portion 68b is in a direction away from the outlet side opening 63bc of the heater support frame 63b from the end of the intersecting portion 68a (air flowing direction) in a state where the air direction adjusting plate 64 is fixed to the flow path forming portion 62. It extends. The first inclined portion 68b is positioned along the longitudinal direction of the first opening 68aa and the second opening 68ab. In this embodiment, the acute angle formed by the surface 68ac of the intersecting portion 68a and the surface 68ba (corresponding to the inclined surface) of the first inclined portion 68b closer to the humidifying rotor 52 is shown in FIG. 9B. Thus, it is designed to be 30 degrees.

  The second inclined portion 68c is positioned along the longitudinal direction of the first opening 68aa and the second opening 68ab, and the side close to the first plate portion 67 among the edge portions parallel to the longitudinal direction of the second opening 68ab. It extends in the direction different from the 1st inclination part 68b from the edge part vicinity. In this embodiment, the acute angle formed by the surface 68ac of the intersecting portion 68a and the surface 68ca (corresponding to the inclined surface) of the second inclined portion 68c closer to the humidifying rotor 52 is shown in FIG. 9B. Thus, it is designed to be 40 degrees.

  In the present embodiment, the angle formed by the surface 68ac of the intersecting portion 68a and the surface 68ba of the first inclined portion 68b and the angle formed by the surface 68ac of the intersecting portion 68a and the surface 68ca of the second inclined portion 68c are as follows. Although it is designed to have different angles, the present invention is not limited to this, and the angle formed by the surface 68ac of the intersecting portion 68a and the surface 68ba of the first inclined portion 68b, the surface 68ac of the intersecting portion 68a, and the second inclined portion. The angle formed by the surface 68ca of 68c may be designed to be the same angle.

  The air heated by the heating wire 63 a flows through the heated air flow channel 66 and travels toward the humidification rotor 52 via the wind direction adjusting plate 64. At this time, the air blown out from the outlet side opening 63bc to the heated air flow channel 66 is regulated by the surface 68ac of the intersecting portion 68a of the airflow direction adjusting plate 64, or passes through the first opening 68aa or the second opening 68ab of the intersecting portion 68a. Passing or being regulated by the surface 68 bb opposite to the surface 68 ba and the surface 68 ba of the first inclined portion 68 b and the surface 68 ca and the surface 68 ca opposite to the surface 68 ca of the second inclined portion 68 c toward the humidifying rotor 52. To reach the humidification rotor 52 (see the arrow in FIG. 6). In addition, the arrow of FIG. 6 has shown an example of the direction to which the air which flows through the heating air flow path 66 goes.

  Here, the inventor measures the temperature in each part of the heated air flow channel 66 in each of the heater 60 and the heater excluding the air direction adjusting plate 64 from the heater 60, and The temperature distribution was analyzed.

  As a result, in the heater in which the air direction adjusting plate 64 is removed from the heater 60, a region on the inner peripheral side of the heated air flow channel 66 (inside the air direction adjusting plate 64 when the air direction adjusting plate 64 of the present embodiment is installed). The temperature of the region) was lower than the temperature of the region on the outer peripheral side of the heated air flow channel 66 (region outside the wind direction adjusting plate 64 when the wind direction adjusting plate 64 of this embodiment is installed). On the other hand, in the heater 60, the temperature difference between the inner peripheral region and the outer peripheral region of the heated air flow channel 66 is such that the heated air flow channel 66 in the heater excluding the air direction adjusting plate 64 from the heater 60. The temperature difference between the inner peripheral region and the outer peripheral region was smaller. Therefore, in the heater 60, the air heated by the heating wire 63 a is uniformly distributed over the entire heated air flow channel 66 by being regulated by the wind direction adjusting plate 64, and is guided without being biased to a part of the humidification rotor 52. The Thereby, the temperature distribution of the humidification rotor 52 can be made to approach uniformly.

  Further, the inventor determines that the humidification amount (the amount of moisture desorbed from the humidification rotor 52) between the air conditioner 10 of the present embodiment and an air conditioner including a heater obtained by removing the wind direction adjusting plate 64 from the heater 60. ) Was measured. As a result, the average amount of humidification per hour was greater in the air conditioner 10 in the present embodiment than in the air conditioner provided with a heater obtained by removing the wind direction adjusting plate 64 from the heater 60. Thus, the air heated by the heating wire 63a is regulated by the wind direction adjusting plate 64 so that it flows not only to the outer peripheral edge of the humidifying rotor 52 but also to the inner peripheral edge, so that the inner peripheral edge and the outer peripheral edge. As a result, the moisture desorption performance of the humidification rotor 52 can be improved. The inner peripheral edge of the humidifying rotor 52 referred to here is a region on the inner peripheral side of the wind direction adjusting plate 64 (see FIG. 6) in a state where the heater 60 is installed above the humidifying rotor 52 (see FIG. 6). The outer peripheral edge of the humidifying rotor 52 is a plan view (see FIG. 6) in a state where the heater 60 is installed above the humidifying rotor 52. It is a region on the outer peripheral side of the wind direction adjusting plate 64 (region on the outer peripheral side of the heated air flow channel 66).

(3-2-4) Intake / Exhaust Fan The intake / exhaust fan 54 is disposed on the side of the humidification rotor 52, and the flow of air taken from the outside and sent to the indoor unit 12 and the indoor unit 12 from the indoors. A centrifugal fan assembly that creates a flow of air that is taken in and sent out of the room. The intake / exhaust fan 54, when sending air taken from the outside to the indoor unit 12, flows outdoor air from the intake / exhaust port 51 d into the humidification flow path 58 b and passes through the humidification rotor 52. An air flow that flows to the indoor unit 12 through the path switching device 53 and the intake / exhaust duct 15 is generated. At this time, air flows in the A1 direction shown in FIG. In addition, when the indoor air is discharged from the indoor unit 12 to the outdoor side, the intake / exhaust fan 54 moves from the indoor unit 12 to the outdoor side through the intake / exhaust duct 15 and the humidification flow path 58b to the outdoor side. Generate a flowing air stream. At this time, air flows in the direction A2 shown in FIG. In addition, the intake / exhaust fan 54 in this embodiment is a turbo fan.

(3-2-5) Channel Switching Device The channel switching device 53 is disposed between the intake / exhaust fan 54 and the intake / exhaust duct 15. Further, the flow path switching device 53 includes a connection state between the intake / exhaust fan 54 and the intake / exhaust duct 15, a supply state in which the humidification flow path 58b and the intake / exhaust duct 15 are connected, and a humidification flow path 58b. It is possible to switch to a supply stop state in which the connection with the intake / exhaust duct 15 is released. In the supply state, the flow of air from the humidification flow path 58b to the intake / exhaust duct 15 or the flow of air from the intake / exhaust duct 15 to the humidification flow path 58b is allowed. For this reason, in the air supply state, the air flowing through the humidification channel 58b and blown out from the intake / exhaust fan 54 flows to the intake / exhaust duct 15 or from the indoor unit 12 through the intake / exhaust duct 15 to the intake / exhaust fan 54. The sucked air flows into the humidifying channel 58b. For this reason, in the air supply state, air flows in the A1 direction shown in FIG. 2, and outdoor air is supplied to the indoor unit 12 through the intake / exhaust duct 15, or air flows in the A2 direction shown in FIG. The air that has passed through the intake / exhaust duct 15 from the indoor unit 12 is exhausted to the outside through the intake / exhaust port 51d. In the supply stop state, the flow of air from the humidification flow path 58b to the intake / exhaust duct 15 or the flow of air from the intake / exhaust duct 15 to the humidification flow path 58b is blocked. For this reason, in the supply stop state, the outdoor air is not supplied into the indoor unit 12 and the air in the indoor unit 12 is not exhausted to the outside.

(3-2-6) Adsorption Fan Device The adsorption fan device 55 includes an adsorption fan motor 59b and an adsorption fan 59a that is rotationally driven by the adsorption fan motor 59b. A flow of air passing through a portion that does not face 60 is generated. That is, the suction blower 55 is sucked in from the first suction air intake port 51b and the second adsorption air intake port 51c, flows through the moisture absorption flow path 58a, and goes out of the adsorption air outlet port 51a to the outdoor. Generates a flow of exhausted air.

(3-2-7) Air flow during humidification operation In the humidification unit 50, during the humidification operation, the suction fan 59a is driven, and air flows in the moisture absorption flow path 58a in the direction of arrow A11-12 in FIG. And the intake / exhaust fan 54 is driven and air flows in the direction of arrow A21-23 in FIG. During the humidification operation, the humidification rotor 52 rotates in the direction of arrow Y in FIG.

  The air flowing in the direction of the arrow A11 passes through the humidification rotor 52 from the first adsorption air intake port 51b and the second adsorption air intake port 51c and travels to the vicinity of the bell mouth 57. This air passes through the portion of the humidification rotor 52 that does not oppose the heater 60 by flowing through the moisture absorption flow path 58a. At this time, moisture in the air is adsorbed by the portion of the humidification rotor 52.

  The air flowing in the direction of the arrow A12 enters the suction blower 55 from the vicinity of the bellmouth 57 through the space surrounded by the bellmouth 57, blows out from the suction blower 55, and travels toward the suction air outlet 51a. .

  The air flowing in the direction of the arrow A21 passes through the humidification rotor 52 from the intake / exhaust port 51d toward the heater 60. The air passes through the first region of the humidification rotor 52 (the region facing the upstream side of the main body 63 of the heater 60 of the humidification flow path 58b). This first region is the arrow Y of the humidification rotor 52. It faces the hygroscopic channel 58a by rotating in the direction.

  The air flowing in the direction of the arrow A22-23 is directed to the flow path switching device 53 by the air heated by the heater 60 passing through the humidification rotor 52. The air flowing in the direction of the arrow A22 is a substantially fan-shaped second region different from the first region of the humidification rotor 52 (a region facing a portion downstream of the main body 63 of the heater 60 of the humidification flow path 58b). Then, the humidifying rotor 52 is heated by passing through a region facing the heated air flow channel 66. This second region faces the portion upstream of the heater 60 of the humidification flow path 58b by the rotation of the humidification rotor 52 in the direction of arrow Y. When the humidification rotor 52 is heated, the moisture adsorbed by the humidification rotor 52 in the air is desorbed to generate humidified air. Then, the humidified air that flows in the direction of the arrow A23 and reaches the flow path switching device 53 is returned again to the flow path switching device 53 via the intake / exhaust fan 54, and passes through the intake / exhaust duct 15 to the indoor unit 12. Sent.

(4) Features (4-1)
Conventionally, by providing an air distribution part with a complicated shape on the downstream side of the heater, the part through which the air heated by the heater passes in the desorption rotor is increased to improve the moisture desorption performance of the desorption rotor. is there. However, in this conventional technique, in order to improve the moisture desorption performance of the desorption rotor, components having a complicated configuration are required.

  Therefore, in the above embodiment, the air flowing through the heated air flow channel 66 is directed so that the air that has passed through the main body 63 is directed toward the humidification rotor 52 by the first inclined portion 68b and the second inclined portion 68c of the airflow direction adjusting plate 64. Be regulated. For this reason, the part through which the air heated in the humidification rotor 52 passes can be increased by the wind direction adjustment board 64 of a simpler structure than before.

  Accordingly, the moisture desorption performance of the humidification rotor 52 can be improved with a simple configuration.

(4-2)
In the above-described embodiment, the intersecting portion 68a is provided with the slit-shaped first opening 68aa and the second opening 68ab along the longitudinal direction. For this reason, the flow path of the air which flows through the heating air flow path 66 can be increased compared with the case where the opening is not provided in the crossing surface.

  Thereby, the part through which the heated air passes in the humidification rotor 52 can be increased.

  Moreover, in the said embodiment, the 1st inclination part 68b is arrange | positioned so that the longitudinal direction of 2nd opening 68ab may be met. For this reason, the air which passed the 2nd opening 68a can be controlled by surface 68bb so that it may go to the humidification rotor 52 side. Further, the second inclined portion 68c is an edge closer to the first plate portion 67 among the edge portions parallel to the longitudinal direction of the second opening 68ab so as to be along the longitudinal direction of the first opening 68aa and the second opening 68ab. It is arranged near the part. Therefore, the air that has passed through the first opening 68aa can be regulated by the surface 68cb so as to be directed toward the humidifying rotor 52, and the air that has passed through the second opening 68ab is directed toward the humidifying rotor 52. It can be regulated by 68ca.

(4-3)
In the above embodiment, the heater support frame 63b and the wind direction adjusting plate 64 are separate components. For this reason, for example, compared with the case where the heater support frame and the wind direction adjusting plate are integrally formed, the air direction adjusting plate 64 having a complicated shape can be easily formed.

(4-4)
In the above-described embodiment, the air direction adjusting plate 64 is disposed in a region near the main body 63 in the heated air flow channel 66. For this reason, the high-temperature air immediately after being blown out from the outlet side opening 63bc can be regulated so as to be directed toward the humidifying rotor 52 side.

(5) Modification (5-1) Modification A
In the above embodiment, the wind direction adjusting plate 64 is disposed in the area near the main body 63 in the heated air flow channel 66.

  Instead of this, the wind direction adjusting plate may be arranged in a region (a rear portion of the humidified air channel) that is separated from the main body in the heated air channel. For example, if the wind direction adjusting plate 164 has the inclined portion 168b so that the air passing through the main body 63 is directed to the humidifying rotor 52 side, the entire wind direction adjusting plate 164 is disposed at the rear portion of the heated air flow channel 66. (See FIG. 11). In addition, as shown in FIG. 11, the wind direction adjusting plate 164 may be arranged so that the heated air flow channel 66 is shortened. Furthermore, when the wind direction adjusting plate 164 is disposed as shown in FIG. 11, the second plate portion 168 may not be provided with an opening.

(5-2) Modification B
In the above embodiment, the heater support frame 63b and the wind direction adjusting plate 64 are separate bodies, and when the heater 60 is assembled, the wind direction adjusting plate 64 is fixed to the heater support frame 63b by screws.

  Alternatively, the wind direction adjusting plate may be a part of the heater support frame. For example, as shown in FIGS. 12 and 13, the heater support frame 263 b and the wind direction adjusting plate part 264 extend from the vicinity of the outlet opening 263 bc of the heater support frame 263 b toward the downstream side of the air flow, as shown in FIGS. H.264 may be integrally formed. As shown in FIGS. 12 and 13, the airflow direction adjusting plate portion 264 is provided with a plurality of slit-shaped openings 268aa, and the edge parallel to the longitudinal direction of the openings 268aa is closer to the outlet side opening 263bc. An inclined portion 268b may extend from the edge of the head toward the side opposite to the humidifying rotor 52. Since the inclined portion 268b is positioned along the longitudinal direction of the slit-shaped opening 268aa, the air heated by the heating wire is regulated by the surface of the inclined portion 268b, and the humidifying rotor 52 side is passed through the opening 268aa. Head for. As described above, when the wind direction adjusting plate portion 264 is provided as a part of the heater support frame 263b, the work of assembling the heater support frame to the wind direction adjusting plate at the time of assembling the heater can be omitted.

(5-3) Modification C
In the above embodiment, the wind direction adjusting plate 64 has the first inclined portion 68b and the second inclined portion 68c, and the surface 68ba that restricts the air flowing through the heated air flow channel 66 toward the humidifying rotor 52 side. , 68bb, 68ca, 68cb are included, but the shape of the wind direction adjusting plate is not limited to this. For example, the wind direction adjusting plate may include only one surface that restricts the air flowing through the heated air flow channel 66 toward the humidifying rotor 52 side, or may include a plurality (five or more).

  The present invention is an invention of a wind direction adjusting plate capable of improving the moisture desorption performance of a desorption rotor with a simple configuration, and is effectively applied to an air conditioner including a humidification unit.

10 Air conditioner 12 Indoor unit (indoor unit)
15 Intake / exhaust duct (humidified air supply path)
20 Outdoor air conditioning unit (outdoor unit)
50 Humidification unit 52 Humidification rotor (desorption rotor)
54 Intake / Exhaust Fan (Fan)
60 heater 62 flow path forming portion 63a heating wire (heater body)
63b Heater support frame 64 Air direction adjusting plate 66 Heated air flow path (flow path)
68aa 1st opening (opening)
68ab 2nd opening (opening)
68ba surface (inclined surface)

JP 2010-144972 A

Claims (6)

An indoor unit (12) installed indoors;
An outdoor unit (20) installed outdoors;
A desorption rotor (52) installed outside and capable of adsorbing moisture contained in outdoor air and desorbing moisture by being heated, and the desorption rotor for desorbing moisture from the desorption rotor A humidifier unit (50) having a heater (60) for heating air passing through the fan, and a fan (54) for generating an air flow for flowing the air heated by the heater to the desorption rotor;
A humidified air supply path (15) that connects the humidifying unit and the indoor unit, and is capable of supplying air containing moisture desorbed from the desorption rotor to the indoor unit;
With
The heater includes a heater main body (63a) as a heating element, an intersecting portion (68a) positioned on the downstream side of the air flow from the heater main body and extending in a direction intersecting the air flow direction, and the intersecting portion. inclined portion extending from the end to the air flow direction (68b) and the wind direction adjusting plate that includes a (64), was closed,
The inclined portion includes an inclined surface (68ba) for restricting the air flow so that air passing through the heater body is directed to the desorption rotor side.
Air conditioner (10). The wind direction adjusting plate is provided with slit-like openings (68aa, 68ab) long in the longitudinal direction of the wind direction adjusting plate,
The inclined surface is disposed along a longitudinal edge of the opening.
The air conditioner according to claim 1. The heater is a separate member from the wind direction adjusting plate, and further includes a heater support frame (63b) that supports the heater body.
The air conditioner according to claim 1 or 2. The wind direction adjusting plate is a part of a heater support frame (263b) that supports the heater body.
The air conditioner according to claim 1 or 2. The heater further includes a flow path forming part (62) that constitutes an air flow path (66) from the heater body toward the desorption rotor,
The wind direction adjusting plate is disposed in a region near the heater body in the air flow path.
The air conditioner according to any one of claims 1 to 4. The heater further includes a flow path forming part (62) that constitutes an air flow path (66) from the heater body toward the desorption rotor,
The wind direction adjusting plate is disposed in a region away from the heater body in the air flow path.
The air conditioner according to any one of claims 1 to 4.

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