JP2011002184A - Humidifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidifier capable of detecting not just a fully closed state when a damper should be in an opened state but even damper malfunction of a half closed state by a simple configuration without a detecting means for detecting opening and closing action of the damper.SOLUTION: A controller 100 has an operating condition decision part 100a deciding an operating condition, a determination criterion value calculating part 100b calculating a determination criterion value for determining malfunction of an opened/closed state of the damper by using a variable for deciding the operating condition by the operating condition decision part 100a, and a damper malfunction determining part 100c determining whether there is damper malfunction of the damper not in an opened state when it should be in the opened state on the basis of a blow-off temperature detected by a blow-off temperature sensor 16 in an ON state of a heater 13 by using the determination criterion value calculated by the determination criterion value calculating part 100b.

Description

  The present invention relates to a humidifier.

  Conventionally, as a humidifier, there is one provided in an air conditioner and provided with a damper in a humidification passage that conveys humidified air from the outside to the inside (see, for example, JP-A-2004-77082 (Patent Document 1)). ). In an air conditioner using this humidifier, the damper is opened during humidification operation or ventilation operation, and the damper is closed when the operation is stopped to close the humidification passage.

  Some of such humidifiers include a damper abnormality detecting device that detects the opening / closing operation of a damper provided in the humidifying passage by a limit switch. However, a detection unit such as a limit switch that detects the opening / closing operation of the damper is provided. If the damper is in the open state, there is a problem that the damper abnormality that is in the closed state cannot be detected.If the damper is in the closed state when the damper should be in the open state, humidification and ventilation can be performed. Absent.

  In such a humidifier, when the damper is in the closed state when the damper is in the closed state, the humidification blowing temperature rises, so that the closed state can be reliably detected using it, but the semi-closed state In such a case, there is a problem that the open state and the semi-closed state cannot be distinguished, and there is a possibility of erroneous detection.

Japanese Patent Laid-Open No. 2004-77082

  Accordingly, an object of the present invention is to provide a humidifier capable of detecting not only a fully-closed state but also a semi-closed state of a damper when the damper should be in an open state with a simple configuration, without detecting means for detecting the opening / closing operation of the damper. Is to provide.

In order to solve the above problems, the humidifying device of the present invention provides:
A moisture absorption passage,
A humidification rotor in which an adsorption region is arranged in the moisture absorption path;
A humidifying passage in which a desorption region of the humidifying rotor is disposed;
A humidifying fan for blowing air into the humidifying passage;
A heater disposed in the humidification passage and upstream of the desorption region of the humidification rotor;
A blowing temperature sensor for detecting a blowing temperature at the outlet of the humidifying passage;
A damper disposed in the humidification passage and downstream of the desorption region of the humidification rotor;
A controller for controlling the humidification rotor, the humidification fan, the heater, and the damper;
The control device
An operation state determination unit for determining an operation state;
A determination reference value calculation unit that calculates a determination reference value for determining an abnormality in the open / close state of the damper, using a variable for determining the operation state by the operation state determination unit;
Based on the blowing temperature detected by the blowing temperature sensor with the heater turned on, using the decision reference value calculated by the decision reference value calculation unit, the damper is opened when the damper should be open. And a damper abnormality determining unit that determines whether or not the damper is not in a state.

  According to the above configuration, the variable for determining the operation state by the operation state determination unit is used, and the detection reference value calculated by the determination reference value calculation unit is used to detect the blower temperature sensor with the heater turned on. Based on the blown-out temperature, the damper abnormality determining unit determines whether or not the damper is in the open state when the damper should be in the open state. Thereby, for example, in the determination reference value calculation unit, the determination reference value corresponding to the blowing temperature detected by the blowing temperature sensor when the damper is in the fully open state is calculated, and the blowing reference temperature sensor is used to calculate the determination reference value. Based on the detected blowing temperature, it can be determined that the damper is in a half-open state. By doing so, it is possible to detect not only the fully-closed state but also the half-open state of the damper with a simple configuration without detecting means for detecting the opening / closing operation of the damper.

Moreover, in the humidifier of one embodiment,
It has an outside temperature sensor that detects the outside temperature,
The variable used for determining the operation state in the operation state determination unit is the outside air temperature detected by the outside air temperature sensor.

  According to the above-described embodiment, the determination reference value calculation unit calculates the determination criterion value of the damper abnormality using the outside air temperature that is a variable for determining the operation state in the operation state determination unit. The damper abnormality can be accurately determined in consideration of the fluctuation of the blowing temperature.

Moreover, in the humidifier of one embodiment,
The variable used to determine the operation state in the operation state determination unit is the output of the heater controlled based on the outside air temperature detected by the outside air temperature sensor.

  According to the above embodiment, the output of the heater is calculated by calculating the determination reference value of the damper abnormality by the determination reference value calculation unit using the output of the heater that is a variable for determining the operation state in the operation state determination unit. The damper abnormality can be accurately determined in consideration of the variation in the blowing temperature due to the above.

Moreover, in the humidifier of one embodiment,
The variable used to determine the operation state in the operation state determination unit is the air volume of the humidification passage.

  According to the above embodiment, the humidification passage is calculated by calculating the determination reference value of the damper abnormality by the determination reference value calculation unit using the air volume of the humidification passage which is a variable for determining the operation state in the operation state determination unit. The damper abnormality can be accurately determined in consideration of the variation of the blowing temperature due to the air volume.

Moreover, in the humidifier of one embodiment,
The variable used for determining the operation state in the operation state determination unit is the rotational speed of the humidifying fan.

  According to the above-described embodiment, by using the rotation speed of the humidifying fan in the operating state determination unit, the determination reference value calculation unit calculates the determination reference value of the damper abnormality, so that the blowout temperature due to the rotation speed of the humidification fan is calculated. A damper abnormality can be accurately determined in consideration of fluctuations.

Moreover, in the humidifier of one embodiment,
A humidifying hose is connected between the outlet downstream of the humidifying passage and the humidified space,
The variable used for determining the operation state in the operation state determination unit is the length of the humidifying hose.

  According to the above embodiment, the humidification hose length, which is a variable for determining the operation state in the operation state determination unit, is used to calculate the determination criterion value of the damper abnormality by the determination criterion value calculation unit. It is possible to accurately determine the damper abnormality in consideration of the variation in the blowing temperature due to the length of the hose.

Moreover, in the humidifier of one embodiment,
The variable used to determine the operation state in the operation state determination unit is the rotational speed of the humidification rotor.

  According to the above embodiment, the humidification rotor rotation speed, which is a variable for determining the operation state in the operation state determination unit, is used to calculate the damper abnormality determination reference value by the determination reference value calculation unit. The damper abnormality can be accurately determined in consideration of the variation in the blowing temperature due to the rotational speed of the rotor.

Moreover, in the humidifier of one embodiment,
It has an outside air humidity sensor that detects outside air humidity,
The variable used for determining the operation state in the operation state determination unit is the outside air humidity detected by the outside air humidity sensor.

  According to the above-described embodiment, the determination reference value for the damper abnormality is calculated by the determination reference value calculation unit using the outside air humidity, which is a variable for determining the operation state in the operation state determination unit, thereby causing the outside air humidity. The damper abnormality can be accurately determined in consideration of the fluctuation of the blowing temperature.

Moreover, in the humidifier of one embodiment,
After the damper abnormality determining unit determines that the damper is abnormal, the control device controls the damper to an initial position before opening and closing the damper.

  According to the above-described embodiment, after the damper abnormality determining unit determines that the damper is abnormal, the control device controls the damper to the initial position before opening and closing the damper next time, so that the damper is frozen or the like. In the damper mechanism in which the position of the damper becomes unstable, the damper can be returned to the normal position by starting the damper, and control can be started. Therefore, for example, when a retry is made after a predetermined time has elapsed since it is determined that the damper is abnormal, the damper control can be accurately performed when the factor such as freezing is eliminated and the damper operates normally.

  As is clear from the above, according to the humidifying device of the present invention, not only a fully closed state but also a semi-closed state when the damper should be in an open state with a simple configuration without detecting means for detecting the opening / closing operation of the damper. Therefore, it is possible to realize a humidifier that can detect the abnormality of the damper.

FIG. 1 is a schematic configuration diagram of an air conditioner including a humidifier according to an embodiment of the present invention. FIG. 2A is a schematic cross-sectional view of the humidifier during a humidifying operation. FIG. 2B is a schematic cross-sectional view of the humidifier during exhaust operation. FIG. 3 is an exploded perspective view of the outdoor unit of the air conditioner. FIG. 4 is an exploded perspective view of the switching damper portion. FIG. 5 is a cross-sectional perspective view showing the air flow in the switching damper portion in the first state. FIG. 6 is a cross-sectional perspective view showing the air flow in the switching damper portion in the second state. FIG. 7A is a schematic cross-sectional view of the main state of the switching damper portion shown in FIG. 2A in the first state. FIG. 7B is a schematic cross-sectional view of the main state of the switching damper portion shown in FIG. 2A in the second state. FIG. 7C is a schematic cross-sectional view of the main state of the switching damper portion shown in FIG. 2A in the third state. FIG. 7D is a schematic cross-sectional view of another example of the switching damper portion. FIG. 8 is a block diagram of a main part of the air conditioner. FIG. 9 is a diagram for explaining the control of the switching damper portion of the control device. FIG. 10 is a flowchart for explaining the control of the switching damper unit.

  Hereinafter, the humidifying device of the present invention will be described in detail with reference to the illustrated embodiments.

  FIG. 1 is a schematic configuration diagram of an air conditioner including a humidifier according to an embodiment of the present invention. As shown in FIG. 1, the air conditioner is placed on an indoor unit 1, an outdoor unit 2 connected to the indoor unit 1 via a communication pipe (not shown), and the outdoor unit 2. The humidifier 3 connected through the indoor unit 1 and the humidifying hose 4 is provided. The humidifier 3 humidifies the outdoor air and supplies the humidified air to the room through the humidifying hose 4 and the indoor unit 1.

  FIG. 2A shows a schematic cross-sectional view of the humidifying device 3 during the humidifying operation. As shown in FIG. 2A, the humidifying device 3 allows the moisture absorbing fan 11 and outdoor air sucked by the moisture absorbing fan 11 to pass therethrough. A disc-shaped humidification rotor 12 having an adsorption region for adsorbing moisture and a desorption region for desorbing moisture, a heater 13 disposed upstream of the desorption region of the humidification rotor 12, and the desorption of the humidification rotor 12 The humidification fan 14 arrange | positioned in the downstream of the area | region, The switching damper part 15 provided in the exit of the humidification passage which passes along the desorption area | region of the said heater 13 and the humidification rotor 12, and the humidification fan 14 is provided. The humidifying rotor 12, the heater 13, the humidifying fan 14, and the switching damper portion 15 are disposed in the humidifying device casing 10.

  The humidifying rotor 12 is formed of a moisture absorbing material such as silica gel, zeolite, or alumina, for example, in the form of a honeycomb or porous multi-grains, and is rotated around a shaft by a humidifying rotor drive motor 37 (shown in FIG. 3). The humidification rotor 12 absorbs moisture (absorbs moisture) when passing through the moisture absorption passage from the outdoor air sucked by the moisture absorption fan 11. On the other hand, when the air heated by the heater 13 on the upstream side of the humidification rotor 12 in the humidification passage passes through the desorption region of the humidification rotor 12, it is humidified by the humidification rotor 12 (moisture is desorbed from the humidification rotor 12). . In this way, the moisture absorbed by the humidification rotor 12 from the outdoor air is desorbed by the air heated by the heater 13, and the air is humidified. The air thus humidified is sent by the humidifying fan 14 to the humidifying hose 4 (shown in FIG. 1).

  2B is a schematic cross-sectional view of the humidifying device 3 during the exhaust operation. As shown in FIG. 2B, the indoor air of the indoor unit 1 is supplied to the humidifying fan 14 via the humidifying hose 4 and the switching damper 15. Inhale and exhaust outside.

  Next, FIG. 3 is an exploded perspective view of the outdoor unit 2 and the humidifier 3 of the air conditioner. In FIG. 3, 21 is a propeller fan, 22 is a front panel, 23 is a closing valve cover, 24 is an electrical component unit, and 25 is a flameproof plate.

  As shown in FIG. 3, the outdoor unit 2 includes a propeller fan 21, a front panel 22, a closing valve cover 23, an electrical component unit 24, a flameproof plate 25, a casing member, and a refrigerant accommodated inside. The outdoor unit body 20 includes circuit components and the like.

  Moreover, the said humidification apparatus 3 has the humidification apparatus casing 10 mounted on the outdoor unit 2, as shown in FIG. A moisture absorption air outlet 10a including a plurality of slit-shaped openings is provided on the front surface of the humidifier casing 10, and the air blows out of the outdoor unit 2 through the moisture absorption air outlet 10a. Further, a moisture absorption air suction port 10b and a supply / exhaust port 10c are provided on the back surface of the humidifier casing 10.

  The upper part of the humidifier casing 10 is covered with a top plate 31. In the humidifier casing 10, the right side of FIG. 3 is a space for accommodating the humidification rotor 12 and the like, and the left side of FIG. 3 is a space for accommodating the moisture absorption fan 11 and the like. In the humidifying device casing 10, a humidifying rotor 12, a heater assembly 35, a humidifying fan assembly 41, a switching damper portion 15, a moisture absorbing side duct 32, a moisture absorbing side bell mouth 33, a moisture absorbing fan 11, and the like are arranged.

  The humidifying rotor 12 is rotatably supported on a support shaft 10d provided on the humidifying device casing 10 side via a rotor guide (not shown). Further, a gear (not shown) formed on the outer peripheral surface of the humidification rotor 12 meshes with a rotor drive gear 38 attached to the drive shaft of the humidification rotor drive motor 37.

  The heater assembly 35 accommodates a heater 13 (shown in FIG. 2A) therein, and heats the air that is taken in from outside and sent to the humidification rotor 12. Further, the heater assembly 35 is disposed so as to cover approximately half (the right half) of the upper surface of the humidification rotor 12. The lower surface of the heater assembly 35 is formed with a suction port for sucking air and a discharge port for discharging the air heated by the heater assembly 35 to the humidification rotor 12 side. The heater assembly 35 is attached above the humidification rotor 12 via a heater support plate 36.

  The humidifying fan assembly 41 is disposed on the side of the humidifying rotor 12, and the humidifying fan 14 (shown in FIG. 2A) and the humidifying fan motor 40 (see FIG. 4) that rotates the humidifying fan 14 at a constant rotational speed. As shown in FIG.

  Further, as shown in FIG. 4, the bottom surface of the humidifying fan assembly 41 is closed by an upper lid 43. The upper lid 43 is provided with an air inlet 43a and an air outlet 43b. The air intake port 43a is an opening through which air sent from the switching damper portion 15 to the humidifying fan assembly 41 passes. The air outlet 43 b is an opening through which air sent from the humidifying fan assembly 41 into the switching damper portion 15 passes.

  The humidifying fan assembly 41 generates a flow of air from the air supply / exhaust port 10c (shown in FIG. 3) to the room through the humidifying rotor 12 (shown in FIG. 3) and the switching damper portion 15, and takes in from outside the room. The air is sent to the indoor unit 1 (shown in FIG. 1) (humidification operation or air supply operation). Conversely, the humidifying fan assembly 41 can also discharge the air taken from the indoor unit 1 to the outside (exhaust operation).

  The humidifying fan assembly 41 passes through the humidifying rotor 12 and descends from the front half of the right half of the humidifying rotor 12 when air taken from outside is sent to the indoor unit 1. The supplied air is sent to the air supply / exhaust duct 60 through the switching damper portion 15. The air supply / exhaust duct 60 is connected to the humidifying hose 4 (see FIG. 1), and air is supplied to the indoor unit 1 via the air supply / exhaust duct 60 and the humidifying hose 4 by the humidifying fan assembly 41.

  On the other hand, when the humidifying fan assembly 41 discharges the indoor air taken in from the indoor unit 1 to the outside, the humidifying fan assembly 41 uses the air sent from the air supply / exhaust duct 60 in the humidifying device casing 10 (shown in FIG. 3). The air is exhausted from the air supply / exhaust port 10c provided on the back surface.

  Next, the operation of the switching damper unit 15 will be described.

  The switching damper unit 15 is switched between a first state (humidification operation or air supply operation), a second state (exhaust operation), and a third state (fully closed state).

  In the first state (humidification operation or air supply operation), the air blown from the humidification fan assembly 41 passes through the humidification hose 4 (shown in FIG. 1) through the air supply / exhaust duct 60 (shown in FIG. 3). And supplied to the indoor unit 1.

  In the second state (exhaust operation), the air that has passed through the humidifying hose 4 and the air supply / exhaust duct 60 from the indoor unit 1 is exhausted from the humidifying fan assembly 41 to the outside through the air supply / exhaust port 10c.

  Moreover, in the said 3rd state (fully closed state), the path | route which connects the switching damper part 15 and the air supply / exhaust duct 60 is closed, and the flow of the air between the outdoor unit 2 and the indoor unit 1 is interrupted | blocked.

  The moisture absorption side duct 32 shown in FIG. 3 covers a portion of the upper surface of the humidification rotor 12 where the heater assembly 35 is not located (a substantially half portion on the left side). The moisture absorption side duct 32 and the moisture absorption side bell mouth 33 form an air flow path leading from the upper surface of the left half portion of the humidification rotor 12 to the upper portion of the moisture absorption fan storage space S1.

  The hygroscopic fan 11 accommodated in the hygroscopic fan storage space S1 is a centrifugal fan that is rotated by the hygroscopic fan motor 34, and absorbs air by sucking air from the opening 33a of the hygroscopic bell mouth 33 disposed in the upper part. An airflow that flows from the air suction port 10b to the opening 33a through the humidification rotor 12 is generated. And the moisture absorption fan 11 exhausts the dry air which absorbed moisture when passing the humidification rotor 12 toward the front of the humidifier casing 10 from the air outlet 10a for moisture absorption. The air passing through the air flow path formed by the moisture absorption side duct 32 is guided to the moisture absorption fan 11 by the moisture absorption side bell mouth 33 provided in the upper part of the moisture absorption fan storage space S1.

  4 shows an exploded perspective view of the first state of the switching damper portion 15. As shown in FIG. 4, the switching damper portion 15 includes a switching damper casing 44, a damper 45 as an example of a slide type damper, The upper cover 43 and a damper drive motor 50 (see FIG. 8) for rotating the damper 45 are configured. The switching damper portion 15 is disposed below the humidifying fan assembly 41, and switches the air flow when the damper 45 moves along a predetermined arc.

  The switching damper casing 44 has a casing side wall 44a and a casing bottom plate 44b, and the upper part is opened. The casing side wall 44a extends upward from the outer edge of the casing bottom plate 44b and is curved in an arc shape. Further, a casing side opening 44c in which the casing side wall 44a does not exist is provided in a part of the switching damper casing 44, and the space inside the switching damper casing 44 is opened to the side by the casing side opening 44c. An arc-shaped rail 44d that protrudes upward from the casing bottom plate 44b is provided near the center of the casing bottom plate 44b. A space between the rail 44d and the casing side wall 44a is a moving space in which the damper 45 moves. A casing bottom opening 44e is provided in a portion of the casing bottom plate 44b through which the damper 45 passes. The casing bottom opening 44e is connected to a hole of a connecting pipe 44f provided on the back surface of the casing bottom plate 44b. A supply / exhaust duct 60 (shown in FIG. 5) is connected to the connection pipe 44f.

  The upper lid 43 is a plate-like member that closes the upper surface of the switching damper casing 44, and the humidifying fan assembly 41 is mounted thereon. An air intake port 43 a of the upper lid 43, which is an opening through which air sent from the switching damper portion 15 to the humidifying fan assembly 41 passes, is provided so as to face the casing bottom opening 44 e of the switching damper casing 44. In addition, an air outlet 43 b of the upper lid 43, which is an opening through which air sent from the humidifying fan assembly 41 into the switching damper portion 15 passes, is provided above the casing bottom opening 44 e of the switching damper casing 44.

  The damper 45 is a member that switches the flow of air passing through the switching damper portion 15 by moving in the moving space. The damper 45 divides a space in the switching damper casing 44 formed by the switching damper casing 44 and the upper lid 43 into a space S2 inside the damper 45 and a space S3 outside the damper 45 (see FIGS. 7A to 7C). ). The damper 45 mainly includes an inner wall 45a, an outer wall 45b, flat side walls 45c and 45d, and a bottom plate 45e.

  The damper 45 has an opening on the upper side, and a part of the opening is covered with the upper lid 43. The inner wall 45a and the outer wall 45b are curved in a circular arc shape having a central angle of about 90 degrees. The outer side wall 45 b is provided on the casing side wall 44 a side of the switching damper casing 44, and the inner side wall 45 a is provided on the rail 44 d side of the switching damper casing 44. A gear 45f provided on the outer surface of the inner wall 45a meshes with the drive gear 46 of the damper drive motor 50 to transmit the rotation of the damper drive motor 50 (shown in FIG. 8) to the damper 45.

  The flat side walls 45c and 45d are plate-like members that connect the side ends of the inner side wall 45a and the outer side wall 45b, and a side opening 45g is provided in the flat side wall 45c. The side opening 45g is connected to a hole in a pipe 45h provided on the outer surface of the flat side wall 45c. The pipe 45h is bent about 90 degrees downward from the outer surface of the flat side wall 45c. Further, a bottom opening 45i is provided in the bottom plate 45e.

  7A shows a schematic cross-sectional view of the damper 45 of the main part A shown in FIG. 2A in a closed state. The damper 45 is moved horizontally in the humidifier casing 10 by the damper drive motor 50 (shown in FIG. 4). To do. In FIG. 7A, the damper 45 has moved to the left to close the outlet 10a. A blowing temperature sensor 16 is disposed between the humidifying fan 14 and the damper 45 in the humidifying device casing 10. That is, in the humidification passage, the blowing temperature sensor 16 is disposed on the downstream side of the desorption region of the humidification rotor 12.

  7B shows a schematic cross-sectional view of the damper 45 of the main part A shown in FIG. 2A in an open state. In FIG. 7B, the damper 45 moves to the right side to open the outlet 10a.

  Moreover, FIG. 7C has shown the cross-sectional schematic diagram of the damper 45 of the principal part A shown in FIG. 2A in a fully closed state.

  As shown in FIG. 7A, when the bottom opening 45 i is positioned directly above the casing bottom opening 44 e of the switching damper casing 44, the space S <b> 2 inside the damper 45 passes through the air intake port 43 a of the top lid 43. When the opening 45j facing the lower side of the pipe 45h of the damper 45 is positioned directly above the casing bottom opening 44e of the casing bottom plate 44b so as to communicate with the side space and as shown in FIG. 7B. The size of the damper 45, the position of the bottom opening 45i, and the like are determined so that the space S2 inside 45 communicates with the space on the humidifying fan 14 side via the air intake port 43a of the upper lid 43.

  The damper drive motor 50 moves the damper 45 so that the damper 45 is in the first state (humidification or supply) at the position shown in FIGS. 5 and 7A and the second state at the position shown in FIGS. 6 and 7B. Switching between the state (exhaust) and the third state (fully closed) at the position shown in FIG. 7C.

Next, the first state, the second state, and the third state of the switching damper unit 15 will be described.
As shown in FIGS. 5 and 7A, in the first state (humidification or supply air), the space S2 inside the damper 45 communicates with the air outlet 43b through the open upper portion, and the bottom opening 45i is opened. Via the casing bottom opening 44e of the switching damper casing 44. Further, a space S3 outside the damper 45 communicates with the air intake 43a. The passage for guiding humidified air (or outdoor air) that has passed through the heater assembly 35 and the humidifying rotor 12 shown in FIG. 3 to the switching damper portion 15 and the space S3 outside the damper 45 are connected via the casing side opening 44c. Therefore, the humidified air (or outdoor air) that has passed through the heater assembly 35 and the humidifying rotor 12 passes through the air intake 43a as the humidifying fan 14 accommodated in the humidifying fan assembly 41 rotates. And enters the inside of the humidifying fan assembly 41. The humidified air or the outdoor air blown out from the air outlet 43b passes through the space S2 inside the damper 45, the bottom opening 45i of the damper 45, and the casing bottom opening 44e of the switching damper casing 44 from the connection pipe 44f. 15 is sent to the outside. Since the connecting pipe 44f is connected to the humidifying hose 4 (shown in FIG. 1) via the air supply / exhaust duct 60 (shown in FIGS. 3 and 5), the air of the humidifying fan assembly 41 is in the first state. The air blown out from the outlet 43 b is supplied to the indoor unit 1 through the humidifying hose 4. Thus, in the first state, air flows in the direction of the arrow R1 shown in FIGS. 5 and 7A, and humidified air (or outdoor air) is supplied to the indoor unit 1 side through the humidifying hose 4.

  Next, as shown in FIGS. 6 and 7B, in the second state (exhaust), the inside of the connection pipe 44f communicates with the space S2 inside the damper 45 via the pipe 45h. Further, the space S <b> 2 inside the damper 45 communicates with the space on the humidifying fan 14 side via the air intake port 43 a of the humidifying fan assembly 41. Furthermore, the space on the humidifying fan 14 side communicates with the space S3 outside the damper 45 via the air outlet 43b of the humidifying fan assembly 41, and the outdoor unit 2 (shown in FIG. 3) via the casing side opening 44c. ) Leads to the outside passage.

  Therefore, in the second state, air flows in the direction of the arrow R2 shown in FIGS. 6 and 7B, and the air discharged from the indoor unit 1 and passing through the humidifying hose 4 passes through the supply / exhaust duct 60 and opens the casing side portion. It blows out from 44c, and is exhausted to the outside of the outdoor unit 2 through the air supply / exhaust port 10c of the humidifier casing 10 shown in FIG.

  Next, as shown in FIG. 7C, in the third state, the damper 45 is located between the first state and the second state. In the third state, the space on the humidifying fan 14 side communicates with the space S3 outside the damper 45 via the air intake port 43a of the humidifying fan assembly 41. Further, the space on the humidifying fan 14 side communicates with the space S <b> 2 inside the damper 45 through the air outlet 43 b of the humidifying fan assembly 41. However, the bottom opening 45 i of the damper 45 and the opening 45 j below the pipe 45 h are closed by the casing bottom plate 44 b of the switching damper casing 44. Further, the casing bottom opening 44 e of the switching damper casing 44 is also closed by the bottom plate 45 e of the damper 45. Thus, in the third state, the air path connecting the outdoor unit 2 and the indoor unit 1 is closed by the switching damper unit 15.

  FIG. 8 shows a block diagram of the main part of the humidifying device 3. The humidifying device 3 receives signals from the blowing temperature sensor 16, the outside air temperature sensor 17, and the outside air humidity sensor 18 as shown in FIG. Based on this, a control device 100 for controlling the moisture absorption fan motor 34, the heater 13, the humidification fan motor 40, the damper drive motor 50, the humidification rotor drive motor 37, and the like is provided.

  The control device 100 includes a microcomputer, an input / output circuit, and the like, and uses an operation state determination unit 100a that determines an operation state and a variable for determining the operation state in the operation state determination unit 100a. When the damper 45 should be in an open state based on the predicted blown temperature calculation unit 100b as a determination reference value calculation unit for calculating the predicted blown temperature and the predicted blown temperature calculated by the predicted blown temperature calculation unit 100b A damper abnormality determining unit 100c that determines whether or not the damper is not in an open state, and a determination continuation timer 100d that is used when the damper abnormality determining unit 100c determines a damper abnormality.

  FIG. 9 is a diagram for explaining the control of the switching damper unit 15 of the control device 100. As shown in FIG. 9, the damper 45 moves between an air supply position P <b> 1 as the air supply fully open position and an exhaust position P <b> 2 as the exhaust fully open position along an arc centered on the origin O.

  This damper control is performed prior to all operations of the humidifying device 3, and predetermined humidification control is performed after an air path is established.

  As shown in FIG. 9, the damper 45 moves between three states, a fully closed position P3 (shown in FIG. 7C), an air supply position P1 (shown in FIG. 7A), and an exhaust position P2 (shown in FIG. 7B). .

[Fully closed position P3]
When the humidifying device 3 is not operated at all, in order not to cause condensation in the humidifying hose 4, the damper 45 is set to the fully closed position P3 to suppress the air flow. The fully closed position P3 is substantially at the middle position of the damper movable range.

[Air supply position P1]
When operating in a state of introducing outside air such as humidification operation or air supply operation, the air supply position is set to P1.

[Exhaust position P2]
The exhaust position P2 is used during the exhaust operation and the exhaust prevention operation. Even when moving to the exhaust position P2, the damper 45 is moved to the exhaust position P2 after first moving to the supply position P1.

  In the switching damper section 15, the supply position P1 is set as the origin (0 pulse), and a drive pulse is applied to the damper drive motor 50 (shown in FIG. 8), so that all of the supply damper position 15 is changed from the supply position P1 according to the number of drive pulses. It moves to the exhaust position P2 through the closed position P3.

  First, when the power is turned on, the damper 45 is moved to the supply position P1, and the drive pulse is applied to the damper drive motor 50 (shown in FIG. 8) from the supply position P1 as a starting point. The damper 45 is moved to the fully closed position P3.

  Next, in the case of moving from the fully closed position P3 to either the supply position P1 or the exhaust position P2, it is once moved to the supply position P1 and then moved to a predetermined position.

  As described above, even when moving from the fully closed position P3 to the supply position P1 or the exhaust position P2, the position of the damper 45 is temporarily moved to the supply position P1, which is the initial position, so that the position of the damper 45 is frozen. In the damper mechanism that becomes indefinite, the damper 45 can be returned to the normal position by starting the damper 45 in the initial position, and control can be started. Therefore, for example, when a retry is made after a predetermined time has elapsed since it is determined that the damper is abnormal, the damper control can be accurately performed when the factor such as freezing is eliminated and the damper 45 operates normally.

  FIG. 10 shows a flowchart for explaining a process of determining a damper abnormality of the switching damper unit 15 by the control device 100.

  When this process is started, it is determined in step S11 shown in FIG. 10 whether or not the humidifying operation is being performed. If the humidifying operation is being performed, the process proceeds to step S12. If the humidifying operation is not being performed, step S11 is repeated.

  Next, in step S12, the predicted blowing temperature as the determination reference value is calculated by the predicted blowing temperature calculation unit 100b using the variable for determining the driving state in the driving state determination unit 100a.

  Here, the predicted blowing temperature calculated by the predicted blowing temperature calculation unit 100b is a blowing temperature expected when the damper 45 is fully opened and performing a humidifying operation in the current humidifying operation state and environmental conditions.

  Next, it progresses to step S13 and it is determined using the blowing temperature detected by the blowing temperature sensor 16 whether [blowing temperature-predicted blowing temperature]> = alpha (predetermined value). Then, when [blowing temperature−predicted blowing temperature] ≧ α (predetermined value) in step S13, that is, it is determined that the damper 45 is in a half-open state or a closed state than the half-open state, and the process proceeds to step S14.

  On the other hand, when [blowing temperature−predicted blowing temperature] <α (predetermined value) in step S13, the process returns to step S12.

  Next, the determination continuation timer 100d is started in step S14, and the process proceeds to step S15.

  Next, in step S15, it is determined whether the determination continuation timer 100d is over counting. Here, the determination continuation timer 100d counts up when a predetermined time has elapsed since the start.

  If it is determined in step S15 that the determination continuation timer 100d is over-counted, the process proceeds to step S16, the damper abnormality is confirmed, the process proceeds to step S17, and the damper abnormality process is performed. Here, in the damper abnormality process, for example, the energization to the heater 13 is turned off to ensure safety, and then the humidification operation is stopped to notify the user of the damper abnormality, or the damper 45 has a low outside air temperature. When there is a possibility that the air is frozen, the humidification operation is stopped and the freeze release operation for sending the heated air to the humidification passage is performed.

  On the other hand, if the determination continuation timer 100d determines that the count is not over in step S15, the process proceeds to step S18, and the predicted blowing temperature calculating unit 100b calculates the predicted blowing temperature.

  Next, the process proceeds to step S19, and if [blowing temperature−predicted blowing temperature] ≧ α (predetermined value), the process returns to step S15, whereas if [blowing temperature−predicted blowing temperature] <α (predetermined value), Return to step S12.

  When the state in which the damper 45 is not fully opened continues continuously for a predetermined time by the determination continuation timer 100d, a damper abnormality is determined, and if the state in which the damper 45 is not fully open is within a predetermined time, the damper is not abnormal. As a result, it is possible to prevent erroneous detection when there is an overshoot of the blowing temperature that occurs due to a state change.

  The predicted blowing temperature calculation unit 100b is based on the output of the heater 13 as an element indicating the current humidification operation state, the rotation speed of the humidification fan 14, the rotation speed of the humidification rotor 12, and the humidification hose length, and the current environment. Based on the outside air temperature and the outside air humidity as conditions elements, for example, the predicted blowing temperature is calculated by the following equation.

Predicted blowing temperature = A × (heater 13 output) + B × (humidification rotor 12 rotation speed) + C × (humidification fan 14 rotation speed) + D × humidification hose length + E × (outside air temperature) + F × (outside air humidity) + G
However, A, B, C, D, E, F, and G are constants obtained by experiments or the like.

  In addition, although the said formula is a linear expression of each element, in order to raise calculation accuracy, you may employ | adopt expressions, such as a quadratic expression. Further, the predicted blowing temperature may be calculated based on at least one of the plurality of elements, or the predicted blowing temperature may be calculated based on a combination of at least two or more of the plurality of elements. Good. In particular, when the predicted blowing temperature is calculated based on one or two of the plurality of elements, it is preferable to calculate based on the outside air temperature or on the basis of the outside air temperature and the output of the heater 13.

According to the humidifier of the above configuration, the expected blown temperature calculation unit 100b of the control device 100 calculates the expected blown temperature corresponding to the blown temperature detected by the blown temperature sensor 16 when the damper 45 is fully open, Based on the blowing temperature detected by the blowing temperature sensor 16 using the expected blowing temperature,
[Blowing temperature-predicted blowing temperature] ≧ α (predetermined value)
At this time, the damper abnormality determination unit 100c can determine that the damper 45 is in a half-open state. In this way, a humidifier that can detect not only a fully closed state but also a semi-closed state of a damper when the damper 45 should be in an open state with a simple configuration without detecting means for detecting the opening and closing operation of the damper 45 is realized. can do.

  In this embodiment, α (predetermined value) is set so that the half-open state of the damper 45 can be detected. However, by setting a plurality of α (predetermined values), not only the half-open state of the damper 45 but also more You may enable it to detect an open / close state finely.

  Further, by calculating the predicted blowing temperature (judgment reference value) using the outside air temperature which is a variable for determining the driving state in the driving state determination unit 100a of the control device 100, the blowing temperature caused by the outside air temperature. The damper abnormality can be accurately determined in consideration of the fluctuation of

  In addition, by using the output of the heater 13 which is a variable for determining the operation state in the operation state determination unit 100a, the predicted output temperature (determination reference value) is used for the output temperature of the heater 13 due to the output of the heater 13. The damper abnormality can be accurately determined in consideration of the fluctuation.

  Further, by calculating the predicted blowing temperature (determination reference value) using the rotation speed of the humidifying fan 14 which is a variable for determining the operation state in the operation state determining unit 100a, the rotation speed of the humidifying fan 14 is calculated. It is possible to accurately determine the damper abnormality in consideration of the variation in the resulting blowing temperature.

  Further, by calculating the predicted blowing temperature (determination reference value) using the length of the humidifying hose 4 which is a variable for determining the operating state in the operating state determining unit 100a, the length of the humidifying hose 4 is calculated. It is possible to accurately determine the damper abnormality in consideration of the variation in the resulting blowing temperature.

  In addition, by using the rotational speed of the humidifying rotor 12 that is a variable for determining the operating state in the operating state determining unit 100a, the predicted blowout temperature (determination reference value) of the damper abnormality is calculated, whereby the humidifying rotor 12 It is possible to accurately determine the damper abnormality in consideration of the variation in the blowing temperature caused by the rotation speed.

  Further, by calculating the predicted blowing temperature (determination reference value) using the outside air humidity which is a variable for determining the driving state in the driving state determining unit 100a, the variation in the blowing temperature caused by the outside air humidity is taken into consideration. Thus, the damper abnormality can be accurately determined.

  In the above embodiment, the damper abnormality is notified after the damper abnormality is determined and the damper such as the freeze release operation is performed. However, the present invention is not limited to this, and several times (or a predetermined time) after the damper abnormality is determined. If the damper abnormality is not resolved despite trying to correct the damper position, it may be displayed on the remote controller or the like for notification.

  Moreover, although the said embodiment demonstrated the humidifier provided in the air conditioner, you may apply this invention only to a humidifier.

DESCRIPTION OF SYMBOLS 1 ... Indoor unit 2 ... Outdoor unit 3 ... Humidification device 4 ... Humidification hose 10 ... Humidification device casing 11 ... Humidifier fan 12 ... Humidification rotor 13 ... Heater 14 ... Humidification fan 15 ... Switching damper part 16 ... Outlet temperature sensor 17 ... Outside temperature Sensor 18 ... Outside air humidity sensor 20 ... Outdoor unit body 21 ... Propeller fan 22 ... Front panel 23 ... Shut-off valve cover 24 ... Electrical component unit 25 ... Flameproof plate 31 ... Top plate 32 ... Hygroscopic side duct 33 ... Hygroscopic side bell mouth 34 ... Hygroscopic fan motor 35 ... Heater assembly 36 ... Heater support plate 37 ... Humidification rotor drive motor 38 ... Rotor drive gear 40 ... Humidation fan motor 41 ... Humidification fan assembly 43 ... Upper lid 43a ... Air intake 43b ... Air outlet 44 ... Switching damper casing 45 ... Damper 46 ... Driving gear 50 ... Damper driving motor 60 ... Supply / exhaust duct DOO 100 ... control device 100a ... driving state determining unit 100b ... predicted outlet temperature calculating unit 100c ... damper abnormality determining unit 100d ... determination continuation timer

Claims (9)

A moisture absorption passage,
A humidification rotor (12) in which an adsorption region is disposed in the moisture absorption passage;
A humidifying passage in which a desorption region of the humidifying rotor (12) is disposed;
A humidifying fan (14) for blowing air into the humidifying passage;
A heater (13) disposed in the humidification passage and upstream of a desorption region of the humidification rotor (12);
A blowing temperature sensor (16) for detecting a blowing temperature at the outlet of the humidifying passage;
A damper (45) disposed in the humidification passage and downstream of the desorption region of the humidification rotor (12);
A control device (100) for controlling the humidification rotor (12), the humidification fan (14), the heater (13) and the damper (45);
The control device (100)
An operation state determination unit (100a) for determining an operation state;
A determination reference value calculation unit (100b) for calculating a determination reference value for determining an abnormality in the open / closed state of the damper (45) using a variable for determining the operation state by the operation state determination unit (100a). When,
Based on the blowout temperature detected by the blowout temperature sensor (16) with the heater (13) turned on, using the judgment reference value calculated by the judgment reference value calculation unit (100b), the damper A humidifier having a damper abnormality determination unit (100c) for determining whether or not a damper abnormality is not in an open state when (45) should be in an open state. The humidifier according to claim 1,
An outside temperature sensor (17) for detecting the outside temperature is provided,
The humidifying apparatus according to claim 1, wherein the variable used for determining the operation state in the operation state determination unit (100a) is the outside air temperature detected by the outside air temperature sensor (17). The humidifying device according to claim 2,
The variable used to determine the operation state in the operation state determination unit (100a) is the output of the heater (13) controlled based on the outside air temperature detected by the outside air temperature sensor (17). A humidifier characterized by. The humidifying device according to any one of claims 1 to 3,
The humidifying apparatus according to claim 1, wherein the variable used for determining the operating state in the operating state determining unit (100a) is an air volume of the humidifying passage. In the humidification device according to any one of claims 1 to 4,
The humidifying device according to claim 1, wherein the variable used for determining the operating state in the operating state determining unit (100a) is a rotational speed of the humidifying fan (14). In the humidification device according to any one of claims 1 to 5,
A humidifying hose (4) is connected between the outlet downstream of the humidifying passage and the humidified space,
The humidifying device according to claim 1, wherein the variable used for determining the operating state in the operating state determining unit (100a) is the length of the humidifying hose (4). In the humidification device according to any one of claims 1 to 6,
The humidifying apparatus according to claim 1, wherein the variable used for determining the operating state in the operating state determining unit (100a) is a rotational speed of the humidifying rotor (12). In the humidification device according to any one of claims 1 to 7,
An outside air humidity sensor (18) for detecting outside air humidity is provided,
The humidifying device according to claim 1, wherein the variable used for determining the operation state in the operation state determination unit (100a) is the outside air humidity detected by the outside air humidity sensor (18). In the humidification device according to any one of claims 1 to 8,
After the damper abnormality determining unit (100c) determines that the damper is abnormal, the control device (100) controls the damper (45) to open and close the damper (45) before opening and closing the damper (45). A humidifier characterized by being positioned.

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