JP6565713B2 - humidifier - Google Patents

Description

  The present invention relates to a humidifier.

  Patent Document 1 describes a humidifier. The humidifier described in Patent Literature 1 humidifies and cleans indoor air. The humidifier described in Patent Document 1 has two outlets. Cleaned air and humidified air are blown out from the two outlets. The two outlets are open on the side of the container frame. The two outlets are open in the same direction.

Japanese Utility Model Publication No.4-1334

  In the above Patent Document 1, humidified air and purified air are blown out in the same direction. Humidified air is diffused by the cleaned air. For this reason, the reach distance of the humidified air is short. The humidifier described in Patent Literature 1 cannot clean the air in the entire room while supplying the humidified air to a desired position.

  The present invention has been made to solve the above problems. An object of the present invention is to obtain a humidifier that can perform humidification and cleaning of air at the same time and has a longer reach of the humidified air.

A humidifier according to the present invention includes an airflow generating means for generating an airflow, a water storage section for storing water, a humidifying means for humidifying air with water stored in the water storage section, a cleaning means for cleaning air, 1 duct, 2nd duct, and 3rd duct are provided. The airflow generation means is provided inside the main body. A 1st duct conveys the air humidified by the humidification means to the 1st blower outlet by the airflow generated by the airflow generation means. The second duct conveys the air cleaned by the cleaning means to the second air outlet by the air flow generated by the air flow generating means. The third duct conveys the air cleaned by the cleaning means to the third outlet through the airflow generated by the airflow generation means. The air conveyed to the first air outlet by the first duct is blown out laterally with respect to the main body. The air transported to the second air outlet by the second duct is blown out in a direction that does not interfere with the flow of air that is transported to the first air outlet by the first duct and blown out. The air conveyed to the third air outlet by the third duct is blown out laterally with respect to the main body. The 1st blower outlet and the 3rd blower outlet are arranged side by side up and down.

  The humidifier according to the present invention includes a first duct that conveys air humidified by the humidifying means to the first air outlet and a second duct that conveys air purified by the cleaning means to the second air outlet. The air conveyed to the first air outlet is blown out in the lateral direction with respect to the main body. The air conveyed to the second air outlet is blown out in a direction that does not interfere with the flow of air that is conveyed to the first air outlet by the first duct and blown out. For this reason, humidification and cleaning of air can be performed simultaneously, and a humidifier with a longer reach of the humidified air can be obtained.

It is a perspective view which shows the humidifier of Embodiment 1 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the humidification cleaning driving | operation of Embodiment 1 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the humidification driving | operation of Embodiment 1 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the air cleaning driving | operation of Embodiment 1 of this invention. It is a flowchart which shows an example of operation | movement of the humidifier of Embodiment 1 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the humidification driving | operation of Embodiment 2 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the air cleaning driving | operation of Embodiment 2 of this invention. It is a perspective view which shows the humidifier of Embodiment 3 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the humidification driving | operation of Embodiment 3 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the air cleaning driving | operation of Embodiment 3 of this invention. It is a flowchart which shows an example of operation | movement of the humidifier of Embodiment 3 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the humidification driving | operation of Embodiment 4 of this invention. It is a longitudinal cross-sectional view which shows the humidifier at the time of the air cleaning driving | operation of Embodiment 4 of this invention. It is a flowchart which shows an example of operation | movement of the humidifier of Embodiment 4 of this invention. It is a hardware block diagram of a control apparatus.

  Embodiments of the present invention will be described below with reference to the drawings. In addition, in each figure, the same part or an equivalent part attaches | subjects the same code | symbol, and abbreviate | omits the overlapping description.

Embodiment 1 FIG.
FIG. 1 is a perspective view showing a humidifier 100 according to Embodiment 1 of the present invention. FIG. 2 is a longitudinal sectional view showing the humidifier 100 during the humidifying / cleaning operation of the first embodiment of the present invention. The humidifier 100 is a device that performs a humidifying and cleaning operation. The humidification cleaning operation is an operation for purifying indoor air while humidifying a humidification target. In the humidification cleaning operation of the present embodiment, humidified air and purified air are blown out simultaneously in different directions. In the humidification cleaning operation of the present embodiment, the humidified air is blown out toward the humidification target. The humidification target includes, for example, a user's face.

  As shown in FIGS. 1 and 2, the humidifier 100 includes a main body 1 and a water supply tank 2. The water supply tank 2 is detachably attached to the main body 1. The user can replenish water in the water supply tank 2 removed from the main body 1.

  Here, in the present embodiment, the left-right direction on the paper surface of FIG. Further, the vertical direction on the paper surface of FIG. The direction perpendicular to the paper surface of FIG. 2 is the left-right direction of the present embodiment. The front-rear direction and the left-right direction are included in the horizontal direction. The water supply tank 2 is attached to the upper part of the rear side of the main body 1, for example.

  The humidifier 100 includes a water storage unit 3. Water is stored in the water reservoir 3. For example, as shown in FIG. 2, the water reservoir 3 is provided inside the rear side of the main body 1. Water is supplied from the water supply tank 2 to the water reservoir 3.

  For example, a tank receiver 4 is formed in the water reservoir 3. The tank receiving part 4 has a concave shape that opens upward. A space is formed in the tank receiver 4 by this opening. The water supply tank 2 is formed with, for example, a mounting portion 5. The water supply tank 2 is attached to the main body 1 so that the attachment portion 5 faces downward. The water supply tank 2 is attached to the main body 1 such that the attachment portion 5 enters the tank receiving portion 4. The attachment portion 5 is open downward when the water supply tank 2 is attached to the main body 1.

  The water supply tank 2 is provided with a water supply valve 6 as an example. For example, as shown in FIG. 2, the water supply valve 6 is located between the lower surface of the water supply tank 2 and the attachment portion 5 in a state where the water supply tank 2 is attached to the main body 1. The water supply valve 6 opens when the water supply tank 2 is attached to the main body 1. The water supply valve 6 is closed when the water supply tank 2 is removed from the main body 1.

  When the water supply tank 2 is attached to the main body 1, the water supply valve 6 is opened, and the water in the water supply tank 2 is supplied to the opening of the attachment portion 5. Water is supplied to the water storage part 3 from the opening of the attachment part 5. Thereby, water is stored in the water storage section 3. As an example, water is stored in the water storage portion 3 so that the water level is the height of the opening of the attachment portion 5.

  The humidifier 100 includes a steam generation unit 7 as an example of a humidifying unit. The steam generation unit 7 is provided, for example, inside the main body 1. The steam generation unit 7 is a part that humidifies air with water supplied from the water storage unit 3.

  The steam generation unit 7 includes, for example, an evaporating dish 8, a heater 9, and a steam cover 10. The evaporating dish 8 is a dish-shaped part. The bottom of the evaporating dish 8 is open as shown in FIG. The opening at the bottom of the evaporating dish 8 is connected to the bottom of the water storage unit 3 by, for example, a hose 11. Water is supplied to the evaporating dish 8 from the water storage unit 3 via the hose 11. As a result, water is stored in the evaporating dish 8. The material of the evaporating dish 8 is a metal such as aluminum.

  The heater 9 is provided on the outer periphery of the side surface of the evaporating dish 8, for example. The steam cover 10 is provided above the evaporating dish 8. The steam cover 10 is provided so as to cover the evaporating dish 8 as shown in FIG. A hole penetrating vertically is formed on the upper surface of the steam cover 10.

  The heater 9 heats the evaporating dish 8. When the evaporating dish 8 is heated by the heater 9, the water stored in the evaporating dish 8 is heated. The water stored in the evaporating dish 8 boils when heated. When the water stored in the evaporating dish 8 boils, steam W1 is generated. The steam W <b> 1 is released from the hole on the upper surface of the steam cover 10 to above the steam generation unit 7. The air above the steam generator 7 is humidified by the steam W1. The steam generation unit 7 can humidify the air in such a simple operation.

  The humidifier 100 includes a high-temperature and high-humidity air duct 12 as an example of the first duct. The high-temperature and high-humidity air duct 12 is a cylindrical part that is open at both ends. For example, as shown in FIG. 2, the high-temperature and high-humidity air duct 12 is provided so that the opening at one end is located inside the main body 1. The high-temperature and high-humidity air duct 12 is provided so that the opening at one end faces downward. The high-temperature and high-humidity air duct 12 is provided so as to take in the steam W1 released from the steam generation unit 7.

  The high-temperature and high-humidity air duct 12 has a curved shape, for example. For example, as shown in FIG. 2, the high-temperature and high-humidity air duct 12 is formed so as to extend toward the front of the main body 1 after extending upward from an opening at one end. The high-temperature and high-humidity air duct 12 may have a bent shape that is bent at, for example, 90 degrees.

  The other end of the high-temperature and high-humidity air duct 12 opens toward the front of the main body 1. This opening at the other end of the high temperature and high humidity air duct 12 is a high temperature and high humidity air outlet 13. The high temperature and high humidity air outlet 13 is an example of a first outlet. The high-temperature and high-humidity air outlet 13 opens forward with respect to the main body 1, that is, laterally with respect to the main body 1. The high temperature and high humidity air outlet 13 is an example of a first outlet. The high-temperature and high-humidity air outlet 13 allows the space inside the high-temperature and high-humidity air duct 12 to communicate with the space in front of the main body 1. The air humidified by the steam generation unit 7 is conveyed to the high temperature and high humidity air outlet 13 by the high temperature and high humidity air duct 12.

  For example, a guard rib 14 may be provided in the high-temperature and high-humidity air duct 12. The guard rib 14 is provided so as to prevent foreign objects and the user's hand from entering the inside of the high-temperature and high-humidity air duct 12. The guard rib 14 is provided in the vicinity of the high temperature and high humidity air outlet 13, for example. Thereby, for example, the user's hand is prevented from touching a high-temperature space heated by the heater 9. Further, foreign matter is prevented from falling into the steam generation unit 7 after entering the inside of the high-temperature and high-humidity air duct 12.

  Note that the bottom surface of the portion of the high-temperature, high-humidity air duct 12 that extends to the high-temperature, high-humidity air outlet 13 toward the front of the main body 1 may be inclined upward toward the high-temperature, high-humidity air outlet 13. In this example, for example, dew condensation water generated in the high-temperature and high-humidity air duct 12 stays inside the high-temperature and high-humidity air duct 12 or the steam generation unit 7. Condensed water generated in the high-temperature and high-humidity air duct 12 does not leak out of the main body 1 from the high-temperature and high-humidity air outlet 13.

  An intake port 15 is opened at the rear of the main body 1. The intake port 15 is formed to take air from the outside of the main body 1 into the main body 1. As shown in FIG. 2 as an example, the intake port 15 is formed below the water reservoir 3.

  The humidifier 100 includes a blower duct 16. The air duct 16 is a cylindrical part. One end of the air duct 16 is open. The opening at this one end of the air duct 16 is an air flow intake port 17. As shown in FIG. 2, the air duct 16 is provided so that the air flow inlet 17 faces downward in the main body 1.

  For example, as shown in FIG. 2, the shape of the air duct 16 is a shape that extends upward from the air flow inlet 17 and then branches into two. Of the blower duct 16, the two branches are a clean air duct 18 and a transport air duct 19, respectively. The clean air duct 18 is an example of a second duct. The carrier air duct 19 is an example of a third duct.

  As shown in FIG. 2, the clean air duct 18 is formed to extend upward from the main body 1. The clean air duct 18 is formed with a clean air outlet 20 that opens upward with respect to the main body 1. The clean air outlet 20 is an example of a second outlet. The clean air outlet 20 allows the space inside the clean air duct 18 to communicate with the space above the main body 1.

  As shown in FIG. 2, the carrier air duct 19 is formed to extend toward the front of the main body 1. The carrier air duct 19 is formed so as to pass above the high-temperature and high-humidity air duct 12 as an example. The carrier air duct 19 is formed with a carrier air outlet 21 that opens toward the front of the main body 1. That is, the carrier air outlet 21 opens in the lateral direction with respect to the main body 1. The carrier air outlet 21 is an example of a third outlet. The carrier air outlet 21 makes the space inside the carrier air duct 19 communicate with the space in front of the main body 1.

  The carrier air outlet 21 and the high-temperature and high-humidity air outlet 13 are arranged side by side as an example. For example, the carrier air outlet 21 is formed above the high-temperature and high-humidity air outlet 13 as shown in FIGS.

  As shown in FIG. 2, an intake air passage 22 is formed in the lower part inside the main body 1. The intake air passage 22 is a space from the intake port 15 to the airflow intake port 17. The humidifier 100 includes a fan 23. The fan 23 is provided inside the main body 1. The fan 23 is disposed, for example, in the intake air passage 22. The fan 23 is an example of an airflow generation unit that generates an airflow.

  The fan 23 includes a motor 23a and a blade portion 23b. The motor 23a and the wing part 23b are connected. The motor 23a rotates the wing part 23b. The fan 23 takes in the room air W2 from the air inlet 15 to the inside of the main body 1 as shown in FIG. Further, the fan 23 generates an air flow from the intake port 15 toward the air flow intake port 17 by the rotation of the blade portion 23b.

  The humidifier 100 includes an air cleaning filter 24 as an example of a cleaning unit that cleans air. For example, as shown in FIG. 2, the air purification filter 24 is provided inside the intake air passage 22. The air cleaning filter 24 is provided between the air inlet 15 and the fan 23, for example. The air purifying filter 24 is provided in the vicinity of the intake port 15 so as to cover the intake port 15, for example.

  The air purification filter 24 is a filter that removes dust contained in the air. The air cleaning filter 24 is detachably provided from the main body 1, for example. The user can remove the air purification filter 24 from the main body 1 and clean it.

  The room air W <b> 2 taken in by the fan 23 passes through the air cleaning filter 24. The indoor air W2 that has passed through the air cleaning filter 24 becomes clean air W3. The clean air W3 is guided to the airflow intake port 17 by the airflow generated by the fan 23. The clean air W <b> 3 is guided from the air flow intake port 17 into the air duct 16.

  A part of the clean air W <b> 3 guided into the blower duct 16 is guided to the clean air duct 18 by the air flow generated by the fan 23. A part of the clean air W3 guided to the clean air duct 18 is referred to as clean air W4. The clean air duct 18 conveys the clean air W4 to the clean air outlet 20 by the airflow generated by the fan 23. The clean air W <b> 4 conveyed to the clean air outlet 20 is blown upward with respect to the main body 1 by the air flow generated by the fan 23.

  Further, a part of the clean air W <b> 3 guided into the blower duct 16 is guided to the transport air duct 19 by the air flow generated by the fan 23. A part of the clean air W3 guided to the carrier air duct 19 is referred to as carrier air W5. The carrier air duct 19 conveys the carrier air W <b> 5 to the carrier air outlet 21 by the air flow generated by the fan 23. The transport air W <b> 5 transported to the transport air outlet 21 is blown forward with respect to the main body 1 by the air flow generated by the fan 23.

  The carrier air duct 19 may be provided with, for example, a wind direction adjusting unit 19a. The air direction adjusting unit 19a adjusts the air direction of the carrier air W5 blown from the carrier air outlet 21. The air direction adjusting unit 19a is a plate-like member, for example. For example, as shown in FIG. 2, the air direction adjusting unit 19 a is provided on the upper edge of the carrier air outlet 21. The wind direction adjusting unit 19a is provided, for example, such that its tip protrudes forward from the carrier air outlet 21. For example, the rear end of the wind direction adjusting unit 19a is pivotally supported from the left-right direction. The wind direction adjusting portion 19a is provided so as to be rotatable around a pivoted rear end.

  Inside the high-temperature and high-humidity air duct 12, for example, a steam mixing space 25 is formed above the steam generation unit 7 as shown in FIG. In addition, a guide air passage 26 that connects the space in the air duct 16 and the steam mixing space 25 is formed inside the main body 1. The guide air passage 26 is formed, for example, at a position offset in the horizontal direction with respect to the center of the steam mixing space 25.

  The guide air passage 26 guides a part of the clean air W <b> 3 guided into the blower duct 16 to the steam mixing space 25. Inside the steam mixing space 25, the clean air W3 guided by the guide air passage 26 and the steam W1 are mixed.

  The steam mixing space 25 may be formed in a cylindrical shape, for example. The steam W1 and the clean air W3 flowing into the cylindrical steam mixing space 25 are efficiently mixed while swirling with each other.

  By mixing the steam W1 and the clean air W3, the high-temperature and high-humidity air W6 is generated. The high-temperature and high-humidity air duct 12 conveys the high-temperature and high-humidity air W6 to the high-temperature and high-humidity air outlet 13 by the air flow generated by the fan 23. The high-temperature and high-humidity air W6 conveyed to the high-temperature and high-humidity air outlet 13 is blown forward with respect to the main body 1 by the airflow generated by the fan 23.

  As shown in FIG. 2, the carrier air W <b> 5 and the high-temperature and high-humidity air W <b> 6 are blown out so as to be mixed while being laterally translated with respect to the main body 1. The carrier air W5 and the high-temperature and high-humidity air W6 are mixed while exchanging heat with each other in the vertical direction. The mixed carrier air W5 and high-temperature and high-humidity air W6 are humidified air W7. The humidified air W7 is sent out toward the humidification target.

  Further, the humidifier 100 may include an air path switching valve 27. The air path switching valve 27 is, for example, a plate-like valve. The air passage switching valve 27 is provided so as to be able to close the air passage in the clean air duct 18. The air passage switching valve 27 is provided so as to be able to close the air passage in the carrier air duct 19 and the guide air passage 26. The air passage switching valve 27 can also open the air passage in the clean air duct 18 and the air passage in the carrier air duct 19.

  The air path switching valve 27 is, for example, a plate-like valve. For example, a support portion 28 is provided at the upper end of the air path switching valve 27. The support portion 28 is provided with a lower end of the lever 29. For example, as shown in FIG. 2, the support portion 28 is pivotally supported between the clean air duct 18 and the transfer air duct 19 from the left-right direction. The air path switching valve 27 and the lever 29 rotate in the front-rear direction with the support portion 28 as a fulcrum.

  For example, when the lever 29 is tilted forward with the support portion 28 as a fulcrum, the air path switching valve 27 rotates rearward with the support portion 28 as a fulcrum. For example, when the lever 29 is tilted rearward with the support portion 28 as a fulcrum, the air passage switching valve 27 rotates forward with the support portion 28 as a fulcrum.

  For example, a valve drive unit 30 is connected to the lever 29. The valve drive unit 30 is provided, for example, inside the main body 1. The lever 29 is moved by, for example, the valve driving unit 30. The valve drive unit 30 is controlled by energization, for example. The air path switching valve 27, the support unit 28, the lever 29, and the valve driving unit 30 are an example of a switching unit that switches the airflow generated by the fan 23. Note that the lever 29 may protrude upward, for example, outside the main body 1. The lever 29 may be manually operable.

  The humidifier 100 of the present embodiment performs a humidification operation and an air purification operation as an example in addition to the humidification cleaning operation. The humidification operation is an operation in which humidified air is sent to the object to be humidified. The air cleaning operation is an operation for blowing out purified air. The humidifying operation, the air cleaning operation, and the humidifying cleaning operation are switched by switching the airflow generated by the fan 23 to the air path switching valve 27.

  In FIG. 2, the air passage switching valve 27 opens the air passage in the clean air duct 18, the air passage in the carrier air duct 19, and the guide air passage 26. The humidification cleaning operation is performed by driving the fan 23 in a state where the air path in the clean air duct 18, the air path in the carrier air duct 19, and the guide air path 26 are opened.

  FIG. 3 is a longitudinal sectional view showing the humidifier 100 during the humidifying operation according to Embodiment 1 of the present invention. The air path switching valve 27 rotated to the rear side with the support portion 28 as a fulcrum closes the air path in the clean air duct 18. The air path in the clean air duct 18 is called a clean air path. The humidification operation is performed by driving the fan 23 and the heater 9 in a state where the clean air path is closed.

  In a state where the clean air path is closed, the fan 23 generates an air flow toward the high-temperature and high-humidity air outlet 13 and the carrier air outlet 21. In the humidifying operation, the airflow does not go to the clean air outlet 20 as shown in FIG. For this reason, air is not blown out from the clean air outlet 20. In the humidification operation, the humidified air W7 is sent out toward the humidification target.

  FIG. 4 is a longitudinal sectional view showing the humidifier 100 during the air cleaning operation of the first embodiment of the present invention. The air passage switching valve 27 rotated to the front side with the support portion 28 as a fulcrum closes the air passage in the carrier air duct 19 and the guide air passage 26. The air path in the carrier air duct 19 and the guide air path 26 are collectively referred to as a humidified air path. The air cleaning operation is performed by driving the fan 23 in a state where the humidified air passage is closed.

  In a state where the humidified air passage is closed, the fan 23 generates an air flow toward the clean air outlet 20. In the air cleaning operation, as shown in FIG. 4, the airflow does not go to the high-temperature and high-humidity air outlet 13 and the carrier air outlet 21. For this reason, air is not blown out from the high-temperature and high-humidity air outlet 13 and the carrier air outlet 21. In the air cleaning operation, as shown in FIG. 4, the clean air W3 guided into the air duct 16 does not branch. The clean air W3 is blown upward from the clean air outlet 20.

  Further, the humidifier 100 may include various sensor systems. The various sensor systems include an air cleanliness detection unit 31 and a humidity detection unit 32 as an example. The air cleanliness detection unit 31 is an example of a cleanness detection means that detects the cleanliness of indoor air. The humidity detection unit 32 is an example of a humidity detection unit that detects indoor humidity.

  For example, as shown in FIG. 2, the air cleanliness detector 31 is provided above the air clean filter 24 inside the main body 1. The air cleanliness detection unit 31 is provided in the vicinity of the intake port 15. The air cleanliness detection unit 31 includes, for example, a dust sensor and an odor sensor. The dust sensor detects dust in the room air W2. The odor sensor detects the odor in the indoor air W2. The air cleanliness detection part 31 detects the air cleanliness of the indoor air W2 with a dust sensor and an odor sensor. In addition, the air cleanliness detection part 31 may have only one of a dust sensor or an odor sensor.

  For example, as shown in FIG. 2, the humidity detector 32 is provided above the air purification filter 24 inside the main body 1. The humidity detector 32 is provided in the vicinity of the air inlet 15. The humidity detection part 32 is comprised by the humidity sensor which detects absolute humidity, for example. Moreover, the humidity detection part 32 may have a room temperature sensor which detects the temperature of the indoor air W2. The humidity detector 32 may detect the relative humidity using, for example, a humidity sensor and a room temperature sensor.

  Further, the humidifier 100 may include, for example, a human detection unit 33 as one of various sensor systems. The human detection unit 33 is disposed on the front surface of the main body 1, for example. As an example, the person detection unit 33 includes a human sensor that detects the presence of a person and a distance sensor that detects a distance to the person. The person detection unit 33 detects the presence / absence of a person in the room where the humidifier 100 is placed and the distance from the humidifier 100 to the person by using, for example, a human sensor and a distance sensor. Moreover, the person detection part 33 may have a sensor which detects that a person is approaching the high temperature, high humidity air blower outlet 13, for example.

  In addition, the humidifier 100 according to the present embodiment includes a control device 34. The control device 34 is provided, for example, inside the main body 1. The various sensor systems described above are connected to the input side of the control device 34. Each device provided in the humidifier 100 is connected to the output side of the control device 34. As an example, the heater 9, the fan 23, and the valve drive unit 30 are connected to the output side of the control device 34. For example, the control device 34 controls each device connected to the output side by energization based on signals received from various sensor systems.

  The control device 34 according to the present embodiment includes a storage unit 34a as an example of a storage unit. The storage unit stores a plurality of operation modes. The plurality of operation modes include, for example, a humidification operation mode, an air cleaning operation mode, and a humidification cleaning operation mode. The storage unit 34a may store a post-cleaning humidification operation mode as one of a plurality of operation modes.

  The humidification operation mode is an operation mode in which the humidification operation shown in FIG. 3 is performed. The air cleaning operation mode is an operation mode in which the air cleaning operation shown in FIG. 4 is performed. The humidification cleaning operation mode is an operation mode in which the humidification cleaning operation shown in FIG. 2 is performed. The post-cleaning humidification operation mode is an operation mode in which the humidification operation is performed after the air cleaning operation is performed for a predetermined time.

  The control device 34 according to the present embodiment includes a control unit 34b as an example of a control unit. The control unit 34 b is a part that controls each device connected to the output side of the control device 34. The control unit 34b controls the valve drive unit 30 by energization based on detection results of various sensor systems connected to the input side of the control device 34, for example.

  An operation display unit 35 is provided on the front surface of the main body 1 as an example. The operation display unit 35 is communicably connected to the control device 34. The operation display unit 35 includes, for example, an operation unit 35a and a display unit 35b.

  The user can change the setting of the humidifier 100 by the operation unit 35a, for example. The operation unit 35a includes, for example, a power switch and an operation switch. The power switch is for turning the humidifier 100 on or off. When the power source of the humidifier 100 is turned on or off, the operation of the humidifier 100 is started or stopped.

  The operation unit 35a is connected to the control unit 34b, for example. The control unit 34b operates based on the operation of the operation unit 35a by the user. For example, when the power switch of the operation unit 35a is turned on, the control unit 34b turns on the power of the humidifier 100. For example, when the power switch of the operation unit 35a is turned off, the control unit 34b turns off the power of the humidifier 100. The power switch of the operation unit 35a may directly turn on or off the humidifier 100 without using the control unit 34b.

  The user can select one operation mode from among a plurality of operation modes stored in the storage unit 34a, for example, by operating the operation unit 35a. The operation unit 35a in this example is an example of a selection unit that selects an operation mode. The operation mode is selected by, for example, an operation switch in the operation unit 35a.

  The control unit 34b has a function of reading information from the storage unit 34a. For example, the control unit 34b reads information on the selected operation mode from the storage unit 34a. The control unit 34b operates based on information read from the storage unit 34a.

  The display unit 35b displays the state of the humidifier 100. The display unit 35b includes a lamp such as an LED. The display unit 35b displays the state of the humidifier 100, for example, by turning on and off the lamp. The control device 34 controls lighting and extinguishing of the lamp of the display unit 35b.

  Next, the operation of the humidifier 100 will be described. FIG. 5 is a flowchart showing an example of the operation of the humidifier 100 according to Embodiment 1 of the present invention. The power supply of the humidifier 100 is turned on, for example, when the user turns on the power switch of the operation unit 35a. (Step S1). When the power is turned on, the operation of the humidifier 100 is started.

  For example, after turning on the power switch, the user selects an operation mode using the operation switch. When the power is turned on in step S1, the control unit 34b reads information on the operation mode selected by the operation switch from the storage unit 34a. The control unit 34b determines the selected operation mode based on the read information (step S2).

  When determining that the air cleaning operation mode is selected, the control unit 34b operates the valve driving unit 30 so that the humidified air passage is closed. As shown in FIG. 4, the humidified air passage is closed by the air passage switching valve 27 (step S3). When the humid air passage is closed in step S3, the clean air passage is open.

  When the humidified air path is blocked in step S3, the control unit 34b drives the fan 23. The controller 34b drives the fan 23 so that the air volume of the clean air W3 supplied by the fan 23 becomes an appropriate amount. For example, the controller 34b drives the fan 23 so that the amount of air blown by the fan 23 is maximized (step S4).

  When the fan 23 is driven in step S4, the air cleaning operation shown in FIG. 4 is started. As shown in FIG. 4, the clean air W3 is blown upward from the clean air outlet 20 without branching. Air is not blown out from the high-temperature and high-humidity air outlet 13 and the carrier air outlet 21.

  When the control unit 34b drives the fan 23 in step S4, the control unit 34b determines the first end condition (step S5). The first end condition is, for example, that the power switch of the operation unit 35a is turned off. As an example, when the control unit 34b detects that the power switch of the operation unit 35a is turned off, the control unit 34b determines that the first end condition is satisfied.

  The first end condition is not limited to this example. For example, the first setting time may be set in advance in the storage unit 34a. In step S5, the control unit 34b may determine that the first end condition is satisfied when the elapsed time since the fan 23 is driven in step S4 is equal to or longer than the first set time. The first setting time may be set by the operation unit 35a, for example.

  When determining that the first end condition is not satisfied in step S5, the control unit 34b continues the determination in step S5 until the first end condition is satisfied. Thus, the air cleaning operation is continued until the first termination condition is satisfied. When determining that the first termination condition is satisfied, the control unit 34b turns off the power to the humidifier (step S6). When the power is turned off, the air cleaning operation ends.

  When determining that the post-cleaning humidification operation mode is selected in Step S2, the control unit 34b operates the valve drive unit 30 so as to close the humidification air path as in Step S3 (Step S7). When the humidified air path is closed in step S7, the controller 34b drives the fan 23 as in step S4 (step S8).

  When the control unit 34b drives the fan 23 in step S8, the control unit 34b determines the switching condition (step S9). The switching condition is, for example, that the elapsed time after the fan 23 is driven in step S4 is equal to or longer than the switching setting time. The switching setting time is preset in the storage unit 34a, for example. Note that the switching setting time may be set by the operation unit 35a, for example.

  When determining that the switching condition is not satisfied in step S9, the control unit 34b determines whether the power switch of the operation unit 35a is turned off (step S10). When determining that the power switch is turned off, the control unit 34b turns off the power to the humidifier as in step S6. Thereby, the air cleaning operation ends. When determining that the power switch is not turned off, the control unit 34b performs the determination in step S9 again.

  Moreover, if the control part 34b determines with switching conditions being satisfy | filled by step S9, it will operate the valve drive part 30 so that a clean air path may be obstruct | occluded. As shown in FIG. 3, the clean air path is closed by the air path switching valve 27 (step S11). Thereby, the air cleaning operation ends. That is, in the post-cleaning humidifying operation mode, the air cleaning operation is performed for a certain period of time until the power switch is turned off or until the switching condition is satisfied.

  If it determines with the humidification operation mode having been selected by step S2, the control part 34b will perform the same operation | movement as said step S11. As shown in FIG. 3, the clean air path is closed by the air path switching valve 27. When the clean air path is closed in step S11, the humid air path is open.

  When the clean air path is closed in step S11, the control unit 34b drives the fan 23 and the heater 9. For example, when the fan 23 is already driven in the post-cleaning humidification operation mode, the control unit 34b causes the fan 23 to continue driving. For example, the control unit 34b drives the fan 23 so that the air volume of the clean air W3 supplied by the fan 23 becomes an appropriate amount. For example, the controller 34b drives the fan 23 so that the amount of air blown by the fan 23 is smaller than that in the air cleaning operation (step S12).

  When the fan 23 and the heater 9 are driven, the humidification operation shown in FIG. 3 is started. As shown in FIG. 3, air is not blown out from the clean air outlet 20. Air is blown out from the carrier air outlet 21 and the high-temperature and high-humidity air outlet 13. In the humidification operation, the humidified air W7 is sent out toward the humidification target. The air volume of the humidified air W7 during the humidifying operation is smaller than the air volume of the clean air W3 during the air cleaning operation.

  The humidification target of the humidifier 100 is, for example, the face of a sleeping user. The humidifier 100 is used by being placed in the vicinity of the sleeping position of the user, for example, at a position away from the user's face by 0.75 [m]. The humidifier 100 is used so that the humidified air W7 hits the user's face. When the wind speed of the air hitting the face is 0.5 [m / s] or less, the user is in a comfortable state without feeling blown.

  During the humidification operation, the fan 23 is controlled such that the air volume of the clean air W3 is 0.2 [m ^ 3 / min] or less, for example. For example, the fan 23 has a wind speed of 0.7 [m / s] at the carrier air outlet 21 and a wind speed of 1.0 [m / s] at the high-temperature and high-humidity air outlet 13. Be controlled. Thereby, the wind speed of the humidified air W7 0.75 [m] ahead from the conveyance air outlet 21 becomes 0.25 [m / s]. Note that the control of the fan 23 during the humidifying operation is not limited to this example.

  When the control unit 34b drives the fan 23 and the heater 9 in step S12, the control unit 34b controls the operation of the fan 23 and the heater 9 based on the detection result of the sensor system, for example. Thereby, the driving | running state of the humidifier 100 is adjusted (step S13). Note that the control unit 34b may adjust the states of the fan 23 and the heater 9 based on the operating conditions set in advance by the user. The operating conditions are set in the storage unit 34a by the operation unit 35a, for example.

  As an example, the storage unit 34a stores in advance characteristic data regarding the humidity detected by the humidity detection unit 32, the distance to the humidification target detected by the human detection unit 33, and the humidity at the position of the humidification target. . The storage unit 34a stores, for example, an appropriate humidity range in advance.

  As an example, the control unit 34b calculates the humidity at the position of the humidification target based on the characteristic data stored in the storage unit 34a and the detection result by the sensor system. The control unit 34b causes the fan 23 and the heater 9 to intermittently operate based on the calculated humidity and the appropriate humidity range stored in the storage unit 34a. For example, when the calculated humidity exceeds the appropriate humidity range, the control unit 34b causes the fan 23 and the heater 9 to stop. For example, when the calculated humidity falls below this humidity range, the control unit 34b puts the fan 23 and the heater 9 into a driving state.

  Control part 34b will judge the 2nd end condition, if the state of operation of humidifier 100 is adjusted at Step S13 (Step S14). The second end condition is, for example, that the power switch of the operation unit 35a is turned off. As an example, when detecting that the power switch of the operation unit 35a is turned off, the control unit 34b determines that the second end condition is satisfied.

  The second end condition is not limited to this example. For example, the second setting time may be set in advance in the storage unit 34a. The control unit 34b may determine that the second end condition is satisfied when the elapsed time since the fan 23 and the heater 9 are driven in step S12 is equal to or longer than the second set time. The second setting time may be set by the operation unit 35a, for example.

  If it is determined in step S14 that the second end condition is not satisfied, the control unit 34b continues the operation adjustment in step S13 and the determination in step S14 until the second end condition is satisfied. Thereby, the humidification operation is continued until the second end condition is satisfied. If it determines with the 2nd completion | finish condition being satisfy | filled by step S14, the control part 34b will turn off the power supply of a humidifier similarly to said step S6. Thereby, the humidification operation is completed.

  If it determines with the humidification cleaning operation mode having been selected by step S2, the control part 34b will operate the valve drive part 30 so that both a humidification air path and a clean air path may be opened. As shown in FIG. 2, the air path switching valve 27 opens both the humid air path and the clean air path (step S15).

  When the humid air path and the clean air path are opened in step S15, the control unit 34b drives the fan 23 and the heater 9. The controller 34b drives the fan 23 so that the air volume of the clean air W3 supplied by the fan 23 becomes an appropriate amount. For example, the control unit 34b drives the fan 23 so that the amount of air blown by the fan 23 is maximized (step S16).

  When the fan 23 and the heater 9 are driven in step S16, the humidification cleaning operation shown in FIG. 2 is started. As shown in FIG. 2, the airflow generated by the fan 23 goes to the clean air outlet 20, the carrier air outlet 21, and the guide air passage 26. The clean air W <b> 3 flows so as to branch to the clean air outlet 20, the carrier air outlet 21, and the guide air passage 26.

  In the humidification cleaning operation, air is blown out from the carrier air outlet 21 and the high temperature and high humidity air outlet 13. In the humidification cleaning operation, the humidified air W7 is sent out toward the humidification target. Further, the clean air W4 is blown upward from the clean air outlet 20.

  When the control unit 34b drives the fan 23 and the heater 9 in step S16, the control unit 34b operates in the same manner as in step S13 and step S14. That is, the humidifying and cleaning operation is continued until the second end condition is satisfied. The operation of the fan 23 and the heater 9 during the humidifying / cleaning operation is controlled by the control unit 34b as in step S13. If it determines with the 2nd completion | finish condition being satisfy | filled, the control part 34b will operate | move similarly to said step S6. When the humidifier 100 is turned off, the humidifying / cleaning operation ends.

  The humidifier 100 of the above embodiment may include a water storage detection unit (not shown), for example. The water storage detection unit detects the presence or absence of water in the water supply tank 2. The water storage detection unit is configured by, for example, a sensor that detects the water level in the water storage unit 3. For example, the control unit 34b may perform the determination in step S14 based on the detection result of the water storage detection unit. For example, the control unit 34b may determine that the second end condition is satisfied when the water storage detection unit detects that there is no water in the water supply tank 2.

  In addition, the humidifier 100 may include a duct temperature detection unit (not shown), for example. The duct temperature detector detects the temperature inside the high-temperature and high-humidity air duct 12. The duct temperature detection part is comprised by the temperature sensor etc. which were provided in the high temperature / humidity air duct 12, for example. For example, the control unit 34b may perform the determination in step S14 based on the detection result of the duct temperature detection unit. For example, the control unit 34b may determine that the second end condition is satisfied when the temperature detected by the duct temperature detection unit is equal to or greater than an allowable range. The allowable temperature range in the high-temperature and high-humidity air duct 12 is set in advance in the storage unit 34a, for example.

  The human detection unit 33 may have a function of detecting that a human body has come into contact with the main body 1 or the high-temperature and high-humidity air duct 12 or the like. The control unit 34b may perform the determination in step S14 based on the detection result of the human detection unit 33, for example. For example, the control unit 34b may determine that the second end condition is satisfied when the human detection unit 33 detects that the human body is in contact with the main body 1 or the high-temperature and high-humidity air duct 12.

  Moreover, the control part 34b may operate the valve drive part 30 so that the air volume of the clean air W3 branched to a humidification air path may be 0.2 [m ^ 3 / min] or less by the said step S15, for example. As an example, the controller 34b operates the valve drive unit 30 so that 10% of the clean air W3 branches to the humidified air passage and 90% to the clean air passage.

  The humidifier 100 of the above-described embodiment is configured such that, for example, the amount of air blown from the clean air outlet 20 during the humidifying and cleaning operation is larger than the amount of air blown from the carrier air outlet 21. Also good.

  For example, in step S15, the control unit 34b operates the valve drive unit 30 so that the amount of air blown from the clean air outlet 20 is larger than the amount of air blown from the carrier air outlet 21. Also good. If it is this example, the user can be in the comfortable state without a feeling of being blown in the case of humidification cleaning operation. Moreover, the efficiency of the air cleaning in the humidification cleaning operation is good.

  The high-temperature and high-humidity air duct 12, the clean air duct 18, and the carrier air duct 19 may be formed, for example, such that the pressure loss in the clean air passage is smaller than the pressure loss in the humid air passage. The clean air duct 18 is formed in a straight line as an example. The carrier air duct 19 is formed in a curved shape. Since the pressure loss in the clean air passage is small, air is efficiently blown out from the clean air outlet 20. Further, since the pressure loss in the humidified air passage is large, the wind speed of the clean air W3 guided to the humidified air passage is reduced.

  That is, the amount of air blown from the clean air outlet 20 is larger than the amount of air blown from the carrier air outlet 21. Thereby, the efficiency of the air cleaning in the air cleaning operation and the humidification cleaning operation is good. In addition, the user can be in a comfortable state without feeling blown during the humidifying operation and the humidifying and cleaning operation.

  The humidifier 100 of the above embodiment performs a humidification cleaning operation. The humidifier 100 can simultaneously humidify and clean the air. Further, during the humidifying / cleaning operation, the humidified air W7 is blown laterally with respect to the main body 1. The clean air W4 is blown upward with respect to the main body 1. For this reason, there is little influence on the flow of humidified air W7 by the flow of clean air W4. If it is the said Example, the reachable distance of the humidification air W7 sent toward a humidification object will become longer.

  In the above embodiment, the humidified air W7 is blown forward with respect to the main body 1. The forward direction is an example of a horizontal direction. For example, the clean air W4 may be blown out in the direction other than the upward direction as long as it does not interfere with the flow of the humidified air W7. For example, the clean air outlet 20 may open rearward with respect to the main body 1. The clean air W4 may be blown backward with respect to the main body 1, for example. The clean air W4 is blown in a direction that does not interfere with the flow of the humidified air W7, and thus does not significantly affect the flow of the humidified air W7. If it is this example, the reach | attainment distance of the humidification air W7 sent toward a humidification object will become longer similarly to the said Example.

  When the humidified air W7 is blown forward, the clean air W4 may be blown in the left-right direction as a direction that does not hinder the flow of the humidified air W7, for example. Moreover, the clean air W4 may be blown off in a diagonally forward direction, for example. The clean air W4 may be blown in a direction that does not hinder the flow of the humidified air W7 blown in the lateral direction. The clean air outlet 20 as an example of the second outlet may be formed so that the clean air W4 does not hinder the flow of the humidified air W7. Since the clean air W4 does not hinder the flow of the humidified air W7, the reach distance of the humidified air W7 becomes longer.

  In addition, the humidifier 100 does not need to be provided with the conveyance air duct 19, for example. For example, the humidifier 100 may be configured to directly send the high-temperature and high-humidity air W6 to the humidification target without being mixed with the carrier air W5. In this example as well, the humidifier 100 capable of simultaneously performing humidification and cleaning of the air while increasing the reach distance of the air sent toward the humidification target is obtained as in the above embodiment.

  In the said Example, the conveyance air blower outlet 21 and the high temperature / humidity air blower outlet 13 are arrange | positioned along with up and down. As shown in FIGS. 2 and 3, the carrier air W <b> 5 and the high-temperature and high-humidity air W <b> 6 are blown out so as to be mixed from above and below while being translated laterally with respect to the body 1. Thereby, the humidified air is delivered to a farther position.

  The high-temperature and high-humidity air W6 is generated from the steam W1 generated by boiling water. The high-temperature and high-humidity air W6 has a higher temperature than the room temperature. For this reason, the high-temperature high-humidity air W6 blown out from the high-temperature high-humidity air outlet 13 tends to rise. On the other hand, the carrier air W5 is at room temperature. The carrier air W5 is sent out in the lateral direction without rising. The carrier air W5 blown out in the lateral direction prevents the high temperature and high humidity air W6 from rising. Thereby, diffusion of the high temperature and high humidity air W6 is suppressed. If it is the said Example, the humidifier 100 which can deliver warm air with high humidity to a far position will be obtained.

  The carrier air W5 blown forward from the carrier air outlet 21 may be blown downward, for example, compared to the horizontal. That is, the carrier air W5 may be blown out in a direction that intersects the wind direction of the high-temperature and high-humidity air W6. The direction in which the carrier air W5 is blown out is adjusted by, for example, the wind direction adjusting unit 19a. For example, the high temperature and high humidity air duct 12 and the conveyance air duct 19 may be formed so that the direction in which the conveyance air W5 is blown out and the direction in which the high temperature and high humidity air W6 is blown out. In this example, the carrier air W5 and the high-temperature and high-humidity air W6 are translated while being mixed more efficiently. Thereby, the reach distance of the humidified air W7 becomes longer.

  The humidifier 100 of the above embodiment includes an air path switching valve 27, a support portion 28, a lever 29, and a valve driving portion 30 as an example of a switching unit. Thereby, the humidifier 100 of the said Example can perform not only a humidification cleaning operation but a humidification operation and a cleaning operation.

  Moreover, the humidifier 100 of the said Example has the memory | storage part 34a as an example of a memory | storage means. A plurality of operation modes are stored in the storage unit 34a. The plurality of operation modes include a humidification operation mode and an air cleaning operation mode. The humidifier 100 includes an operation unit 35a that is an example of a selection unit and a control unit 34b that is an example of a control unit. Thus, the user can easily switch between the humidification operation and the clean operation by operating the operation unit 35a.

  The plurality of operation modes in the embodiment include a post-cleaning humidification operation mode. When the post-cleaning humidifying operation mode is selected, the humidifier 100 performs the humidifying operation after performing the air cleaning operation for a certain period of time. When the post-cleaning humidification operation mode is selected, the humidifier 100 can blow out the cleaner humidified air W7 toward the humidification target.

  In the above embodiment, the control unit 34b determines the switching condition in step S9. The switching condition is not limited to the above embodiment. For example, the controller 34b may determine that the switching condition is satisfied when the air cleanliness detected by the air cleanliness detector 31 is equal to or higher than a reference. The standard of air cleanliness is preset in the storage unit 34a, for example.

  In addition, the switching setting time in the above embodiment may be calculated and set based on, for example, the air cleanliness detected by the air cleanliness detection unit 31. That is, the time of the air cleaning operation performed when the post-cleaning humidification operation mode is selected may be changed based on the air cleanliness level. In this example, the time of the air cleaning operation performed before the humidifying operation in the post-cleaning humidifying operation mode becomes a more appropriate time.

  When the post-cleaning humidification operation mode is selected, the control unit 34b may control the fan 23 based on the air cleanliness detected by the air cleanliness detection unit 31 in step S9. For example, the control unit 34b may control the fan 23 to reduce the output of the fan 23 when the air cleanliness is high. When the post-cleaning humidification operation mode is selected, as an example, the air cleaning operation is performed for a preset switching setting time. In this example, the power consumption is suppressed by reducing the output of the fan 23 during the switching setting time.

  Further, the humidifier 100 is configured such that, for example, when the humidity detected by the humidity detector 32 is equal to or higher than a certain humidity during the humidification operation, the humidification operation is terminated and the air cleanliness operation is started. Also good. In this example, excessive humidification operation is prevented. When the humidifying operation is finished and the air cleaning operation is started, the heater 9 is stopped. In this example, the operation time of the heater 9 is appropriate, so that the temperature in the main body 1 is prevented from becoming excessively high.

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described. FIG. 6 is a longitudinal sectional view showing the humidifier 200 during the humidifying operation of Embodiment 2 of the present invention. FIG. 7 is a longitudinal sectional view showing the humidifier 200 during the air cleaning operation of the second embodiment of the present invention. 6 and 7, the same reference numerals are given to the same configurations as the humidifier 100 of the first embodiment. The description of the same configuration as the humidifier 100 of Embodiment 1 is omitted. The humidifier 200 operates basically the same as the humidifier 100 of the first embodiment.

  The humidifier 200 of the present embodiment is different from the humidifier 100 of the first embodiment in that the carrier air duct 19 has a movable part 36. The movable part 36 is a part that can move in the front-rear direction. The movable part 36 is formed in the site | part from the conveyance air blower outlet 21 to a fixed distance among the conveyance air ducts 19, for example. The movable part 36 is provided so as to rotate the lever 29 in the front-rear direction by moving in the front-rear direction. The movable part 36 is formed to be manually movable, for example.

  In the present embodiment, the lever 29 does not have to protrude above the main body 1 as shown in FIGS. 6 and 7 as an example. Further, the humidifier 200 may not include the valve drive unit 30 as an example.

  When the movable portion 36 moves forward, for example, as shown in FIG. 6, the lever 29 rotates forward with the support portion 28 as a fulcrum. The air passage switching valve 27 rotates rearward with the support portion 28 as a fulcrum. As a result, the clean air passage is closed. When the fan 23 and the heater 9 are driven in a state where the clean air passage is closed, the humidifying operation shown in FIG. 6 is performed.

  When the movable portion 36 moves rearward, for example, as shown in FIG. 7, the lever 29 rotates rearward with the support portion 28 as a fulcrum. The air path switching valve 27 rotates forward with the support portion 28 as a fulcrum. Thereby, a humidification air path is obstruct | occluded. When the fan 23 is driven in a state where the humidified air passage is closed, the air cleaning operation shown in FIG. 7 is performed. In this example, the user can easily switch between the humidifying operation and the air cleaning operation.

  The control unit 34b may control each device in accordance with the movement of the movable unit 36. For example, the control unit 34b stops the heater 9 when the movable unit 36 moves to the rear side. Moreover, the movable part 36 can also move to a position between, for example, the position shown in FIG. 6 and the position shown in FIG. As a result, both the humidified air passage and the clean air passage are opened. The humidifier 200 can perform a humidifying and cleaning operation similarly to the humidifier 100 of the first embodiment.

Embodiment 3 FIG.
Next, a third embodiment of the present invention will be described. FIG. 8 is a perspective view showing a humidifier 300 according to Embodiment 3 of the present invention. FIG. 9 is a longitudinal sectional view showing a humidifier 300 during a humidifying operation according to Embodiment 3 of the present invention. FIG. 10 is a longitudinal sectional view showing the humidifier 300 during the air cleaning operation of the third embodiment of the present invention. Hereinafter, the humidifier 300 will be described with reference to FIGS. 8 to 10.

  8, 9, and 10, the same reference numerals are given to the same configurations as those of the humidifier 100 of the first embodiment. About the humidifier 300 of this Embodiment, description is abbreviate | omitted about the same structure as the humidifier 100 of Embodiment 1. FIG.

  The humidifier 300 includes a main body 1, a water supply tank 2, and a water storage unit 3. The water reservoir 3 is provided with a tank receiver 4. A mounting portion 5 is formed in the water supply tank 2. The water supply tank 2 has a water supply valve 6.

  The humidifier 300 includes an ultrasonic transducer 37 as an example of a humidifying unit. The ultrasonic transducer 37 is provided in the water reservoir 3. The ultrasonic transducer 37 is a device that generates high-humidity air W8 from the water stored in the water storage unit 3.

  The ultrasonic transducer 37 emits ultrasonic waves by vibrating. The ultrasonic transducer | vibrator 37 makes the water of the water storage part 3 into the mist form which is a fine particle with the emitted ultrasonic wave. The ultrasonic vibrator 37 ejects water in a mist shape, for example, above the water reservoir 3. Thereby, the high humidity air W8 is produced | generated.

  The water storage unit 3 or the ultrasonic vibrator 37 may be provided with a sterilization device that reduces germs contained in water. The sterilization apparatus is, for example, an infrared irradiation apparatus or a discharge apparatus. For example, the water storage part 3 or the ultrasonic transducer | vibrator 37 may be formed with the material which has antibacterial property. Thereby, the germs contained in the water in the water storage part 3, for example, and the high-humidity air W8 reduce. In this example, the propagation of germs is suppressed.

  The humidifier 300 includes a high-humidity air duct 38 as an example of the first duct. The high-humidity air duct 38 has a curved cylindrical shape, for example. An air flow inlet 17a is formed at one end of the high-humidity air duct 38. The high-humidity air duct 38 is provided, for example, such that the airflow intake port 17a faces downward in the main body 1.

  The high-humidity air duct 38 is formed so as to extend toward the front of the main body 1 after extending upward from the airflow intake port 17a. A high-humidity air outlet 39 that opens toward the front of the main body 1 is formed at the other end of the high-humidity air duct 38. The high-humidity air outlet 39 opens laterally with respect to the main body 1. The high-humidity air outlet 39 is an example of a first outlet.

  The high-humidity air duct 38 may have a bent shape that is bent at, for example, 90 degrees. Further, the high humidity air duct 38 may be provided with a wind direction adjusting portion 19 a at the upper edge of the high humidity air outlet 39.

  As shown in FIG. 8 and FIG. 9 as an example, the water reservoir 3 of the present embodiment is formed so that a part thereof enters the middle of the high-humidity air duct 38. The ultrasonic transducer 37 is disposed in a portion of the water storage unit 3 that enters the middle of the high-humidity air duct 38.

  The reservoir 3 is open above the ultrasonic transducer 37. The high-humidity air duct 38 is arranged so that the high-humidity air W8 generated by the ultrasonic vibrator 37 is taken into the space in the high-humidity air duct 38. The high-humidity air duct 38 conveys the captured high-humidity air W8 to the high-humidity air outlet 39.

  The humidifier 300 includes a clean air duct 18a as an example of the second duct. The clean air duct 18a corresponds to the clean air duct 18 of the first embodiment. The clean air duct 18a has a straight cylindrical shape as an example. The pressure loss in the clean air duct 18a is smaller than the pressure loss in the curved duct. The clean air duct 18a is open at both ends. An opening at one end of the clean air duct 18a is an air flow intake port 17b.

  The clean air duct 18 a is provided so that the air flow inlet 17 b faces downward within the main body 1. The clean air duct 18a is provided adjacent to the high-humidity air duct 38, for example. The air path in the clean air duct 18a and the air path in the high-humidity air duct 38 are independent. The clean air duct 18a and the high-humidity air duct 38 are provided, for example, such that the airflow intake port 17a and the airflow intake port 17b are arranged side by side.

  Further, as shown in FIGS. 8 and 9, for example, the other end of the clean air duct 18 a protrudes upward from the main body 1. The opening at the other end of the clean air duct 18a is a clean air outlet 20a. The clean air outlet 20a corresponds to the clean air outlet 20 of the first embodiment. The clean air outlet 20 a opens upward with respect to the main body 1. The clean air outlet 20a is an example of a second outlet.

  The humidifier 300 includes a high-temperature transport air duct 40 as an example of the third duct. The high temperature conveyance air duct 40 has, for example, a curved cylindrical shape. An air flow inlet 17 c is formed at one end of the high temperature carrier air duct 40. The high-temperature carrying air duct 40 is provided, for example, such that the air flow inlet 17c faces downward in the main body 1.

  The high-temperature carrying air duct 40 is formed so as to extend upward from the airflow intake port 17 c and then extend toward the front of the main body 1. At the other end of the high-temperature transport air duct 40, a high-temperature transport air outlet 41 that opens toward the front of the main body 1 is formed. The high temperature carrier air outlet 41 is an example of a third outlet. The high temperature transport air duct 40 may have a bent shape that is bent at, for example, 90 degrees.

  The high temperature carrier air duct 40 is provided adjacent to the high humidity air duct 38, for example. The high-temperature carrying air duct 40 is provided along the front side and the lower side of the high-humidity air duct 38, for example. The air passage in the high temperature carrier air duct 40 is independent of the air passage in the clean air duct 18 a and the air passage in the high humidity air duct 38.

  The high-humidity air outlet 39 and the high-temperature transport air outlet 41 are arranged side by side. The high temperature carrier air outlet 41 is disposed below the high humidity air outlet 39. Moreover, the airflow inlet 17c is arrange | positioned ahead of the airflow inlet 17a, for example, as shown in FIG.

  The high-humidity air duct 38 and the high-temperature transport air duct 40 are arranged as described above as an example. The high-humidity air duct 38 is provided along the rear side and the upper side of the high-temperature carrier air duct 40. The high-humidity air duct 38 has a shape that follows the outer shape of the high-temperature transport air duct 40. The diameter of the curved portion of the high-humidity air duct 38 is larger than the diameter of the curved portion of the high-temperature transport air duct 40. The high-humidity air duct 38 is formed so as to be longer than the high-temperature carrying air duct 40.

  Further, the high-temperature transport air duct 40 is provided with a heating unit 42. The heating unit 42 is an example of a heating unit that heats the air conveyed by the high-temperature conveyance air duct 40. The heating unit 42 includes a heater, for example. The heater of the heating unit 42 is provided, for example, in the high temperature carrier air duct 40. For example, the heating unit 42 heats the air in the high-temperature transport air duct 40 with a heater.

  Note that the heater of the heating unit 42 may be provided in an uncurved portion of the high-temperature transport air duct 40. The heater of the heating unit 42 may be provided, for example, in a portion extending upward from the air flow inlet 17c. Thereby, it is prevented that the pressure loss in the curved part of the high temperature conveyance air duct 40 becomes large.

  An intake port 15 is formed at the rear of the main body 1. Further, an intake air passage 22 is formed in the lower part inside the main body 1. The intake air passage 22 of the present embodiment is a space from the intake port 15 to the airflow intake port 17a, the airflow intake port 17b, and the airflow intake port 17c. A fan 23 is provided in the intake air passage 22. The fan 23 includes a motor 23a and a blade portion 23b. The fan 23 takes in the indoor air W2 by the rotation of the wing 23b.

  The fan 23 of the present embodiment is a sirocco fan, for example. The fan 23 is disposed below the airflow inlet 17a, the airflow inlet 17b, and the airflow inlet 17c. The fan 23 is disposed so as to straddle the airflow inlet 17a, the airflow inlet 17b, and the airflow inlet 17c. In the present embodiment, one fan 23 generates airflows toward the three airflow intakes.

  The fan 23 may be an axial fan, for example. For example, a plurality of fans 23 may be provided. A fan 23 may be provided that generates an airflow toward the airflow inlet 17a, the airflow inlet 17b, and the airflow inlet 17c. If it is this example, the airflow which goes to each of the airflow inlet 17a, the airflow inlet 17b, and the airflow inlet 17c is controlled independently.

  Further, the humidifier 300 includes the air purification filter 24 as in the first embodiment. The air cleaning filter 24 cleans the indoor air W2. The air cleaned by the air cleaning filter 24 becomes clean air W3.

  The humidifier 300 includes an air path switching unit 43 as an example of a switching unit that switches the airflow generated by the fan 23. The air path switching unit 43 is provided, for example, below the airflow inlet 17a, the airflow inlet 17b, and the airflow inlet 17c.

  The air path switching unit 43 closes the air path from the fan 23 to the airflow intake port 17b, for example. The air path from the fan 23 to the air flow inlet 17b is referred to as a clean air path in the present embodiment. The humidification operation shown in FIG. 9 is performed by driving the fan 23, the ultrasonic transducer 37, and the heating unit 42 in a state where the clean air path is closed.

  In a state where the clean air passage is closed, the fan 23 generates an airflow toward the airflow inlet 17a and the airflow inlet 17c. As shown in FIG. 9, a part of the clean air W <b> 3 is taken into the inside of the high-humidity air duct 38 from the air flow intake port 17 a by the air flow generated by the fan 23. The clean air W3 taken into the high humidity air duct 38 is mixed with the high humidity air W8 and becomes the high humidity air W9. The high-humidity air W9 is blown out laterally with respect to the main body 1 from the high-humidity air outlet 39.

  Further, as shown in FIG. 9, a part of the clean air W3 is taken into the high-temperature transport air duct 40 from the airflow intake port 17c by the airflow generated by the fan 23. The clean air W <b> 3 taken into the high temperature carrier air duct 40 is heated by the heating unit 42. The heated clean air W3 becomes the high temperature carrier air W10. The high temperature carrier air W <b> 10 is blown out laterally with respect to the main body 1 from the high temperature carrier air outlet 41.

  In the humidification operation shown in FIG. 9, the high-humidity air W9 and the high-temperature carrier air W10 are mixed while being translated in the lateral direction. The mixed high-humidity air W9 and high-temperature transport air W10 are humidified air W11. The humidified air W11 is sent out toward the humidification target.

  The air path switching unit 43 closes, for example, the air path from the fan 23 to the air flow inlet 17a and the air path from the fan 23 to 17c. The air path from the fan 23 to the air flow inlet 17a and the air path from the fan 23 to 17c are collectively referred to as a humidified air path in the present embodiment. When the fan 23 is driven in a state where the humidified air passage is closed, the air cleaning operation shown in FIG. 10 is performed.

  In a state where the humidified air passage is closed, the fan 23 generates an air flow toward the air flow intake port 17b. As shown in FIG. 10, the clean air W3 is taken into the clean air duct 18a from the air flow inlet 17b without branching. The clean air W3 taken into the clean air duct 18a is blown upward with respect to the main body 1 from the clean air outlet 20a.

  Moreover, the air path switching unit 43 can also make the humid air path and the clean air path open. In the state where the humidified air passage and the clean air passage are opened, the humidifying and cleaning operation is performed as in the first and second embodiments.

  Similarly to the first embodiment, the humidifier 300 may include various sensor systems such as an air cleanliness detection unit 31, a humidity detection unit 32, and a human detection unit 33. The humidifier 300 includes the control device 34 and the operation display unit 35 as in the first embodiment. The control apparatus 34 of this Embodiment controls the fan 23, the ultrasonic transducer | vibrator 37, the heating part 42, and the air path switching part 43 by the control part 34b, for example.

  The control device 34 is a device having electronic components. The control device 34 is provided inside the main body 1. The control device 34 of the present embodiment is provided, for example, at a certain distance from the water supply tank 2, the water storage unit 3, the ultrasonic transducer 37, and the high-humidity air duct 38.

  The control device 34 is provided such that the high-temperature transport air duct 40 is positioned between the high-humidity air duct 38 and the like, for example. Moreover, the control apparatus 34 is provided so that the intake air path 22 may be located between the water storage parts 3, for example.

  There may be water or moisture inside the high-humidity air duct 38 and the water reservoir 3. The control device 34 of the present embodiment is provided away from a space where water or moisture is present. The inside of the high-temperature carrying air duct 40 and the intake air passage 22 is a dry space. There is a dry space between the space with water or moisture and the control device 34. In this example, the electronic component included in the control device 34 is protected from water or moisture.

  Next, the operation of the humidifier 300 will be described. FIG. 11 is a flowchart showing an example of the operation of the humidifier 300 according to the third embodiment of the present invention. Steps S101 to S116 in the flowchart of FIG. 11 correspond to steps S1 to S16 of the first embodiment. The humidifier 300 basically operates in the same manner as the humidifier 100 of the first embodiment. Description of operations similar to those in the first embodiment is omitted, and only differences from the first embodiment will be described.

  Steps S101 and S102 are the same as steps S1 and S2 of the first embodiment, and thus description thereof is omitted. When determining that the air cleaning operation mode is selected in step S102, the control unit 34b causes the air path switching unit 43 to block the humid air path (step S103). Step S103 corresponds to step S3 in the first embodiment.

  When the humidified air passage is blocked in step S103, the control unit 34b drives the fan 23 (step S104). In step S104, the control unit 34b drives the fan 23, for example, similarly to step S4 in the first embodiment. When the fan 23 is driven in step S104, the air cleaning operation shown in FIG. 10 is performed. Since the operations after Step S104, that is, Steps S105 and S106 are the same as Steps S5 and S6 of the first embodiment, description thereof is omitted.

  When determining that the post-cleaning humidification operation mode is selected in step S102, the control unit 34b causes the air path switching unit 43 to block the humid air path (step S107). Step S107 corresponds to step S7 in the first embodiment. When the humidified air passage is closed in step S107, the control unit 34b drives the fan 23 (step S108). Of the operations after S108, step S109 and step S110 are the same as step S9 and step S10 of the first embodiment, and a description thereof will be omitted.

  When it determines with the humidification operation mode having been selected by step S102, or when it determines with the switching condition being satisfy | filled by step S109, the control part 34b makes the air path switching part 43 obstruct | occlude a clean air path (step S111). Step S111 corresponds to step S11 of the first embodiment.

  When the clean air path is closed in step S111, the control unit 34b drives the fan 23, the ultrasonic vibrator 37, and the heating unit 42 (step S112). Thereby, the humidification operation shown in FIG. 9 is started. In the humidification operation, the humidified air W11 is sent out toward the humidification target.

  Step S112 corresponds to step S12 of the first embodiment. The control unit 34b controls the fan 23, for example, similarly to step S12 of the first embodiment. For example, the controller 34b controls the fan 23 so that the air volume of the clean air W3 is 0.2 [m ^ 3 / min] or less. If it is this example, the person who is an example of the humidification object will not feel a feeling of blowing in the humidification operation.

  In step S112, the control unit 34b drives the fan 23 and the ultrasonic transducer 37 at the same time as an example. For example, the controller 34b may drive the ultrasonic transducer 37 after a certain time has elapsed since the fan 23 was driven. In this example, the backflow of the high-humidity air W8 to the fan 23 is prevented.

  Since operations after Step S112, that is, Steps S113 and S114 are the same as Steps S13 and S14 of the first embodiment, description thereof is omitted. In addition, the control part 34b of this Embodiment makes the fan 23, the ultrasonic transducer | vibrator 37, and the heating part 42 operate intermittently by step S113 as an example.

  If it determines with the humidification cleaning operation mode having been selected by step S102, the control part 34b will control the air path switching part 43 so that a clean air path and a humidification air path may be open | released (step S115). Step S115 corresponds to step S15 of the first embodiment.

  When the clean air path and the humid air path are opened in step S115, the control unit 34b drives the fan 23, the ultrasonic vibrator 37, and the heating unit 42 (step S116). Thereby, the humidification cleaning operation is started. In the humidification cleaning operation, air is blown out from the clean air outlet 20a, the high-humidity air outlet 39, and the high-temperature transport air outlet 41. Air is blown upward from the clean air outlet 20 a with respect to the main body 1. Air is blown out laterally with respect to the main body 1 from the high-humidity air outlet 39 and the high-temperature transport air outlet 41.

  Step S116 corresponds to step S16 in the first embodiment. The control unit 34b controls the fan 23, for example, similarly to step S16 of the first embodiment. For example, the control unit 34b controls the air path switching unit 43 so that the air volume of the clean air W3 guided to the air flow inlet 17a and the air flow inlet 17b is 0.2 [m ^ 3 / min] or less. May be. After step S116, the operation is the same as that after step S16 of the first embodiment.

  With the above configuration and operation, if the humidifier 300 is used, the same effect as the humidifier 100 of the first embodiment can be obtained. In the case of the humidifier 300, the reach distance of the humidified air W11 sent toward the humidification target becomes longer. Further, the humidifier 300 can simultaneously clean the indoor air and supply the humidified air W11. Furthermore, in the humidification operation and the humidification cleaning operation, a person who is an example of a humidification object does not feel a feeling of being blown.

  As in the first embodiment, the air blown from the clean air outlet 20a during the humidifying and cleaning operation affects the flow of air blown from the high-humidity air outlet 39 and the high-temperature carrier air outlet 41. As long as the direction is not given, it may be blown out other than the upward direction. In addition to the upward direction, the clean air outlet 20a may be opened, for example, in the backward direction, the left-right direction, or the diagonally forward direction.

  In the said Example, the high-humidity air blower outlet 39 and the high temperature conveyance air blower outlet 41 are arrange | positioned along with up and down. For example, as shown in FIG. 9, the high-humidity air W <b> 9 and the high-temperature carrier air W <b> 10 are blown out so as to be mixed from above and below while being translated laterally with respect to the main body 1.

  The high-humidity air W8 is generated by mist-like water. For this reason, the high humidity air W8 is a low temperature compared with room temperature. The clean air W3 is at room temperature. For this reason, the high-humidity air W9 in which the clean air W3 and the high-humidity air W8 are mixed is lower in temperature than the room temperature. The high-humidity air W9 blown out in the lateral direction from the high-humidity air outlet 39 tends to descend.

  The high temperature carrier air W10 heated by the heating unit 42 is higher than room temperature. The high temperature carrier air W10 blown out from the high temperature carrier air outlet 41 tends to rise. If it is the said Example, the high-humidity air W9 and the high temperature conveyance air W10 will translate, mixing efficiently. Thereby, the reach distance of the humidified air W11 becomes longer.

  As in the first embodiment, for example, the high-humidity air W9 may be blown out downward from the high-humidity air outlet 39 compared to the horizontal. Thereby, the highly humid air W9 and the high temperature carrier air W10 are mixed more efficiently.

  The humidifier 300 may be configured such that, for example, when the humidifying operation and the humidifying and cleaning operation are finished, the fan 23 is stopped after a predetermined time has elapsed since the ultrasonic vibrator 37 is stopped. That is, after the ultrasonic transducer 37 is stopped, the fan 23 may be additionally driven for a predetermined time.

  During the humidification operation and the humidification cleaning operation, the humidity inside the high-humidity air duct 38 becomes high. In this example, the inside of the high-humidity air duct 38 is dried by the additional driving of the fan 23. Thereby, propagation of miscellaneous bacteria is suppressed.

  Note that the output of the fan 23 at the time of this additional drive may be lower than the output of the fan 23 at the time of humidification operation and humidification cleaning operation, for example. Thereby, the fan 23 is additionally driven in an energy saving and silent state. In addition, when the fan 23 is additionally driven, the display unit 35b may display that the fan 23 is additionally driven.

  In the above embodiment, the heater of the heating unit 42 is controlled by the control unit 34b as an example. The heater of the heating unit 42 may be a self-temperature control type heater such as a PTC heater. The temperature of the heater of the heating unit 42 may not be adjusted by the control unit 34b. If it is this example, adjustment of the temperature of the high temperature conveyance air W10 heated by the heating part 42 is performed more easily and appropriately.

  The humidifier 300 includes an ultrasonic transducer 37 as an example of a humidifying unit. The ultrasonic transducer 37 is a device that can easily and efficiently generate high-humidity air W8. According to the present embodiment, the generation of the high-humidity air W8 and the high-humidity air W9 is performed more easily and efficiently than in the first embodiment.

  The high-humidity air duct 38 is formed to be longer than the high-temperature transport air duct 40. The high humidity air duct 38 is formed to be longer within a limited design range. Thereby, the length of the space where the clean air W3 and the high-humidity air W8 are mixed during the humidification operation becomes longer. During the humidification operation, the clean air W3 and the high humidity air W8 are mixed evenly. Thereby, the high humidity air W9 with few mixing nonuniformity with the clean air W3 and the high humidity air W8 is sent out to a humidification object.

  In addition, a part of the water storage section 3 of the above embodiment enters the high-humidity air duct 38. For example, as shown in FIG. 9, the water storage unit 3, the ultrasonic vibrator 37, and the high-humidity air duct 38 are arranged so that the clean air W3 flows along the side of the high-humidity air W8 during the humidification operation. Also good.

  As an example, the clean air W3 flows from the lower side to the upper side of the high-humidity air W8. As a result, the high-humidity air W8 is easily attracted to the high-humidity air W8. The high-humidity air W8 attracted by the clean air W3 is mixed with the high-humidity air W8 to become the high-humidity air W9. In this example, the high-humidity air W8 is less likely to stay in the high-humidity air duct 38. Thereby, the highly humid air W9 is efficiently generated.

  In addition, the water storage part 3 does not need to partially enter the high-humidity air duct 38. The water reservoir 3 may be provided below the high-humidity air duct 38, for example. The water storage unit 3 provided below the high-humidity air duct 38 and the high-humidity air duct 38 are connected, for example, via a connection duct (not shown). In this example, the high-humidity air W8 is guided to the high-humidity air duct 38 through the connection duct. In this example, since the water storage part 3 does not enter the high humidity air duct 38, the flow of the clean air W3 in the high humidity air duct 38 becomes smooth.

Embodiment 4 FIG.
Next, a fourth embodiment of the present invention will be described. The configuration and operation of the humidifier 400 of the present embodiment are basically the same as the humidifier 300 of the third embodiment. The description of the same configuration and operation as those in Embodiment 3 is omitted. FIG. 12 is a longitudinal sectional view showing a humidifier 400 during a humidifying operation according to Embodiment 4 of the present invention. FIG. 13: is a longitudinal cross-sectional view which shows the humidifier 400 at the time of the air cleaning driving | operation of Embodiment 4 of this invention.

  The humidifier 400 includes a vaporization filter 44 instead of the ultrasonic transducer 37 in the third embodiment as an example of a humidifying unit. The vaporization filter 44 is formed of a material that absorbs water. A material that absorbs water is, for example, rayon. The vaporization filter 44 includes, for example, a water supply unit 44a and an evaporation unit 44b.

  The water supply unit 44 a is immersed in the water in the water storage unit 3. The water supply part 44 a is a part that sucks up water in the water storage part 3. Water is supplied to the evaporation unit 44b from the water supply unit 44a. For example, as illustrated in FIGS. 12 and 13, the vaporization filter 44 is disposed so that the evaporation portion 44 b is located in the high-humidity air duct 38.

  FIG. 14 is a flowchart illustrating an example of the operation of the humidifier 400 according to the fourth embodiment of the present invention. Steps S201 to S216 in the flowchart of FIG. 14 are basically the same as steps S101 to S116 of the third embodiment. Detailed description from step S201 to step S216 will be omitted.

  In step S212 and step 216, the control unit 34b drives the fan 23 and the heating unit 42. When the fan 23 is driven, the clean air W3 flows to the side of the vaporization filter 44, for example, as shown in FIG.

  When the clean air W3 flows to the side of the vaporization filter 44, water evaporates from the evaporation unit 44b. Highly humid air W8 is generated by the evaporated water. When water evaporates from the evaporation unit 44b, water is supplied again from the water supply unit 44a to the evaporation unit 44b by capillary action. In addition, the evaporation part 44b may be formed so that a surface area may become larger than the water supply part 44a, for example. Thereby, water evaporates efficiently from the evaporation part 44b.

  In the present embodiment, by using the vaporization filter 44 as an example of the humidifying means, high-humidity air W8 is generated without using electric power. If it is this Embodiment, the structure and control of the humidifier 400 will become simpler.

  FIG. 15 is a hardware configuration diagram of the control device 34 according to the first to fourth embodiments. The control apparatus 34 has a printed wiring board as an example. On the printed wiring board, a storage circuit, an arithmetic processing unit that executes various control programs stored in the storage circuit, an input / output circuit that inputs and outputs signals to the arithmetic processing unit, and a timer circuit that measures time, It is provided as an example. The memory circuit, the arithmetic processing unit, the input / output circuit, and the timer circuit are collectively referred to as a processing circuit.

  Each function of the storage unit 34a and the control unit 34b of the control device 34 is realized by this processing circuit. The processing circuit may be dedicated hardware 60. The processing circuit may include a processor 61 and a memory 62. A part of the processing circuit is formed as dedicated hardware 60, and may further include a processor 61 and a memory 62. FIG. 15 shows an example in which the processing circuit is partly formed as dedicated hardware 60 and includes a processor 61 and a memory 62.

  When at least a part of the processing circuit is at least one dedicated hardware 60, the processing circuit is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC, an FPGA, or the like. The combination is applicable.

  When the processing circuit includes at least one processor 61 and at least one memory 62, each function of the storage unit 34a and the control unit 34b of the control device 34 is realized by software, firmware, or a combination of software and firmware. Software and firmware are described as programs and stored in the memory 62. The processor 61 reads out and executes the program stored in the memory 62, thereby realizing the function of each unit. The processor 61 is also referred to as a CPU (Central Processing Unit), a central processing unit, a processing unit, an arithmetic unit, a microprocessor, a microcomputer, or a DSP. The memory 62 corresponds to, for example, a nonvolatile or volatile semiconductor memory such as a RAM, a ROM, a flash memory, an EPROM and an EEPROM, or a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, and a DVD.

  Thus, the processing circuit can realize the functions of the storage unit 34a and the control unit 34b of the control device 34 by hardware, software, firmware, or a combination thereof.

  DESCRIPTION OF SYMBOLS 1 Main body, 2 Water supply tank, 3 Water storage part, 4 Tank receiving part, 5 Mounting part, 6 Water supply valve, 7 Steam generation part, 8 Evaporating dish, 9 Heater, 10 Steam cover, 11 Hose, 12 High temperature high humidity air duct, 13 High-temperature and high-humidity air outlet, 14 Guard rib, 15 Air inlet, 16 Air duct, 17 Air current inlet, 17a Air current inlet, 17b Air current inlet, 17c Air current inlet, 18 Clean air duct, 18a Clean Air Duct, 19 Carrying Air Duct, 19a Air Direction Adjusting Unit, 20 Clean Air Blowout, 20a Clean Air Blowout, 21 Carrying Air Blowout, 22 Intake Airway, 23 Fan, 23a Motor, 23b Wing, 24 Air Purifying Filter , 25 steam mixing space, 26 guide air path, 27 air path switching valve, 28 support part, 29 lever, 30 valve drive unit, 31 air cleanliness detection unit, 32 humidity detection unit, 33 human detection unit, 34 control device, 34a storage unit, 34b control unit, 35 operation display unit, 35a operation unit, 35b display unit, 36 Movable parts, 37 Ultrasonic vibrator, 38 High humidity air duct, 39 High humidity air outlet, 40 High temperature carrier air duct, 41 High temperature carrier air outlet, 42 Heating part, 43 Air path switching part, 44 Evaporation filter, 44a Water supply unit, 44b Evaporation unit, 60 Dedicated hardware, 61 Processor, 62 Memory, 100 Humidifier, 200 Humidifier, 300 Humidifier, 400 Humidifier

Claims (12)

An airflow generating means provided inside the body for generating an airflow;
A water storage section for storing water,
Humidifying means for humidifying air with water stored in the water storage section;
A cleaning means for purifying the air;
A first duct that conveys the air humidified by the humidifying means to the first air outlet by the air flow generated by the air flow generating means;
A second duct that conveys the air purified by the cleaning means to the second air outlet by an air flow generated by the air flow generating means;
A third duct that conveys the air purified by the cleaning means to a third outlet through the airflow generated by the airflow generating means;
With
The air conveyed to the first air outlet by the first duct is blown laterally with respect to the main body,
The air conveyed to the second air outlet by the second duct is blown out in a direction that does not interfere with the flow of air that is conveyed to the first air outlet by the first duct and blown out ,
The air conveyed to the third air outlet by the third duct is blown laterally with respect to the main body,
The 1st blower outlet and the 3rd blower outlet are humidifiers arranged side by side up and down . The humidifier according to claim 1 , wherein an air volume of air blown from the second air outlet is larger than an air volume of air blown from the third air outlet. The airflow generated by the airflow generating means is blown out from either one of the second air outlet and the third air outlet or from both the second air outlet and the third air outlet. The humidifier according to claim 1 , further comprising switching means for switching. Storage means for storing a plurality of operation modes;
Selecting means for selecting one operation mode from a plurality of operation modes stored in the storage means;
Control means for controlling the switching means based on the operation mode selected by the selection means;
With
The plurality of operation modes include a humidification operation mode and an air cleaning operation mode,
The control means controls the switching means so that air is not blown out from the second outlet when the humidifying operation mode is selected by the selection means, and the air cleaning operation mode is selected by the selection means. The humidifier according to claim 3 , wherein the switching unit is controlled so that air is not blown from the third outlet. The plurality of operation modes stored in the storage means include a humidification cleaning operation mode,
When the humidifying / cleaning operation mode is selected by the selection means, the control means blows air from both the second air outlet and the third air outlet, and blows air from the second air outlet. The humidifier according to claim 4 , wherein the switching unit is controlled such that the air volume of the air becomes larger than the air volume of the air blown from the third outlet. The plurality of operation modes stored in the storage means include a post-cleaning humidification operation mode,
The control means controls the switching means so that air is not blown from the third outlet when the post-cleaning humidification operation mode is selected by the selection means, and when the predetermined time has elapsed, The humidifier according to claim 4 or 5 , wherein the switching unit is controlled so that air is not blown out from the two outlets. Provided with a cleanliness detection means for detecting the cleanliness of the air,
The humidifier according to claim 6 , wherein the predetermined time is changed based on a detection result of the cleanliness detection means. Provided with a cleanliness detection means for detecting the cleanliness of the air,
The humidifier according to claim 6 , wherein an air volume of air blown out from the second air outlet during the predetermined time is changed based on a detection result of the cleanliness detection means. Humidity detection means for detecting the humidity in the room,
The switching means prevents the air from being blown out from the third air outlet when the humidity detected by the humidity detecting means becomes equal to or higher than a certain humidity when air is being blown out from the third air outlet. The humidifier according to any one of claims 4 to 8 , wherein the humidifier is controlled. The humidifier according to any one of claims 1 to 9 , wherein the humidifying means humidifies the air by heating the water stored in the water storage section to generate steam. The humidifying means humidifies the air by heating the water stored in the water storage unit to generate steam,
The third air outlet, a humidifier according to claims 1 to any one of claims 9 disposed above the first outlet. Heating means for heating the air conveyed by the third duct;
The third air outlet, a humidifier according to claims 1 to any one of claims 9 disposed below the first outlet.

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