JP2017040445A - Humidifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidifier capable of efficiently and properly generating steam according to a degree of temperature change of steam generation water in an intermittent operation of a heater.SOLUTION: A humidifier includes a steam generation device 71 having a main body having a suction port 15 and a supply port 21, a blower fan 62 generating air flow sucked from the suction port 15 and blown off from the supply port 21, a heater 72 heating an evaporation pan 71a storing water and the water in the evaporation pan 71a, generating steam, and humidifying the air in the air flow by the generated steam, a micro computer 100 controlling energization of the heater 72 and energization of a motor 62a for driving the blower fan 62, and a room temperature sensor 161 detecting an indoor temperature. The micro computer 100 alternately repeats a high energization rate state and a low energization rate state of the heater 72, and changes at least one of a duration time of the high energization rate state and a duration time of the low energization rate state according to the indoor temperature detected by the room temperature sensor 161.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a humidifier.

  In a conventional humidifier, a heater that generates steam, a nozzle that discharges the steam generated by the heater to the outside, a humidity detector that detects the humidity at the installation position of the main body that houses the heater, and humidity detection Based on the humidity detected by the unit and the distance from the installation position of the main unit to the position where the person is located, the humidity at the position where the person is located is estimated, and the heater is operated intermittently according to the estimated humidity. And a control unit that adjusts the amount of steam conveyed to a certain position (see, for example, Patent Document 1).

JP, 2014-202408, A

  However, in the conventional humidifier shown in Patent Document 1, when the operation of the heater that heats the water for generating steam is intermittently performed in order to maintain the humidity in the room or the like, heating by the heater is temporarily performed. While shutting down or weakening, the temperature of the water for steam generation decreases. The amount of decrease in water temperature at this time also changes depending on the ambient temperature, that is, room temperature, but this is not taken into consideration in conventional humidifiers, so the temperature change of steam generation water during intermittent operation of the heater is not considered. Depending on the degree, efficient and appropriate steam generation cannot be performed.

  In particular, when the room temperature is low, while the heating by the heater is temporarily stopped or weakened, the temperature of the water for humidification greatly decreases, and it takes time until steam is generated when the heating by the heater is resumed. For this reason, until the production | generation of a vapor | steam is restarted, a vapor | steam does not come out but a moisture retention effect will fall. Furthermore, since only cold air that has not been humidified until then blows out and reaches the user, the user is uncomfortable.

  The present invention has been made to solve such a problem, and is efficient and appropriate depending on the degree of temperature change in steam generation water during intermittent operation of a heater for heating the steam generation water. It is possible to obtain a humidifier capable of generating a large amount of steam.

  In the humidifier according to the present invention, a main body in which an inlet and an outlet are formed, an air blowing fan that generates an airflow that blows out air sucked from the inlet from the outlet, a storage unit that stores water, and the above A heater that heats the water in the reservoir and generates steam; humidifying means that humidifies the air in the airflow with the generated steam; energizing the heater and energizing the motor that drives the blower fan Control means for controlling the temperature of the heater, and temperature detection means for detecting the room temperature, wherein the control means alternates between a high energization rate state and a low energization rate state where the energization rate is lower than the high energization rate state for the heater. And when the room temperature detected by the temperature detecting means is the first temperature, the first control is performed for the duration of the high energization rate state and the duration of the low energization rate state, and the temperature When the indoor temperature detected by the detection means is a second temperature different from the first temperature by a predetermined temperature or more, at least one of the duration of the high energization rate state and the duration of the low energization rate state is the first temperature. The second control is different from the first control.

  Alternatively, in the humidifier according to the present invention, a main body in which an inlet and an outlet are formed, a blower fan that generates an airflow that blows out air sucked from the inlet and the outlet, and a reservoir that stores water And a heater for heating the water in the reservoir to generate steam, humidifying means for humidifying the air in the airflow with the generated steam, and energizing the heater and a motor for driving the blower fan Control means for controlling the energization of the heater, and temperature detection means for detecting the indoor temperature, the control means is a high energization rate state for the heater and a low energization rate state in which the energization rate is lower than the high energization rate state. And alternately changing at least one of the duration of the high energization rate state and the duration of the low energization rate state according to the room temperature detected by the temperature detecting means, and That.

  In the humidifier according to the present invention, it is possible to efficiently and appropriately generate steam according to the degree of temperature change of steam generating water during intermittent operation of the heater that heats steam generating water. There is an effect.

It is the external appearance perspective view which looked at the humidifier which concerns on Embodiment 1 of this invention from diagonally forward. It is the external appearance perspective view which looked at the humidifier which concerns on Embodiment 1 of this invention from diagonally backward. It is the disassembled perspective view which looked at the state which removed the water absorption tank cover of the humidifier which concerns on Embodiment 1 of this invention, and removed the main body cover from the lower case from diagonally back. It is the perspective view which looked at the state which removed the main body cover and water supply tank of the humidifier which concern on Embodiment 1 of this invention from the lower case from diagonally forward. It is the perspective view which looked at the main body cover of the humidifier which concerns on Embodiment 1 of this invention from the downward direction. It is sectional drawing which looked at the humidifier which concerns on Embodiment 1 of this invention from the side. It is sectional drawing which looked at the state with which the main body cover and water supply tank cover of the humidifier which concern on Embodiment 1 of this invention were united. It is a block diagram of the control system of the humidifier which concerns on Embodiment 1 of this invention. It is a figure explaining operation | movement of the humidifier which concerns on Embodiment 1 of this invention. It is a figure explaining operation | movement of the humidifier which concerns on Embodiment 1 of this invention. It is a figure explaining operation | movement of the humidifier which concerns on Embodiment 1 of this invention. It is a figure explaining operation | movement of the humidifier which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the humidifier which concerns on Embodiment 1 of this invention. It is a block diagram of the control system of the humidifier which concerns on Embodiment 2 of this invention. It is a figure explaining operation | movement of the humidifier which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the humidifier which concerns on Embodiment 2 of this invention.

  DESCRIPTION OF EMBODIMENTS Embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and overlapping descriptions are simplified or omitted as appropriate. The present invention is not limited to the following embodiments, and various modifications can be made without departing from the spirit of the present invention.

Embodiment 1 FIG.
1 to 13 relate to Embodiment 1 of the present invention. FIG. 1 is an external perspective view of a humidifier as viewed from an oblique front. FIG. 2 is an external perspective view of the humidifier as viewed from an oblique rear. 3 is an exploded perspective view of the humidifier removed from the lower case with the water tank cover removed, and FIG. 4 is an oblique view of the humidifier body cover and the water tank removed from the lower case. FIG. 5 is a perspective view of the humidifier body cover as viewed from below, FIG. 6 is a sectional view of the humidifier as seen from the side, and FIG. 7 is a view of the humidifier body cover and water tank cover. FIG. 8 is a block diagram of the control system of the humidifier, FIGS. 9 to 12 are diagrams illustrating the operation of the humidifier, and FIG. 13 is a diagram illustrating the operation of the humidifier. FIG.

  As shown in FIGS. 1 and 2, the humidifier 200 according to Embodiment 1 of the present invention includes a lower case 1, a main body cover 2, and a water supply tank cover 3. The lower case 1, the main body cover 2, and the water supply tank cover 3 are collectively referred to as a main body of the humidifier 200. The main body of the humidifier 200 is configured such that an outer main body cover 2 is covered from the upper side of the lower case 1, and a water supply tank cover 3 is attached to the rear surface of the main body cover 2.

  A suction port 15 is formed in the lower part of the rear surface of the lower case 1. The suction port 15 is an opening for taking room air into the main body from the outside of the lower case 1. An air outlet 21 is provided in the upper part of the front surface of the main body cover 2. Details of the air outlet 21 will be described later. A power switch 4 and a setting switch 5 are provided at the lower part of the front surface of the main body cover 2. A power cord (not shown) for supplying commercial power to the humidifier 200 is connected to the power cord connecting portion 17 provided with the power cord connecting portion 17 at the lower part of the rear surface of the lower case 1.

  A movable duct 31 is attached to the upper part of the main body cover 2. The movable duct 31 is provided movably in the front-rear direction within the range of the position shown in FIG. 2 from the position shown in FIG. A blower port 32 is formed in the lower part on the front side of the movable duct 31. A wind direction adjusting plate 33 is provided on the front side of the air blowing port 32. The vertical direction of the wind from the blower opening 32 can be adjusted by the wind direction adjusting plate 33.

  Next, as shown in FIG. 3, a water supply tank 41 is detachably attached to the upper rear side of the lower case 1. A steam duct 51 and a steam generator cover 75 are installed on the front side of the upper portion of the lower case 1. The steam generator cover 75 covers the upper side of the steam generator 71 described later. The steam duct 51 is attached further above the steam generator cover 75.

  The description of the configuration of the humidifier 200 will be continued with reference to FIGS. 4 to 7. As shown in FIG. 4, a display operation unit 11 is provided on the front surface of the lower case 1. The display operation unit 11 includes a power button 4a and a setting button 5a, a light emitting unit 116, light emitting units 117a to 117g, and a light emitting unit 118. Here, the power button 4a and the setting button 5a are collectively referred to as an operation unit 180. The light emitting unit 116, the light emitting units 117a to 117g, and the light emitting unit 118 are collectively referred to as a display unit 150.

  As shown in FIG. 6, an operation board 7 is disposed on the back side of the display operation unit 11 inside the lower case 1. On the operation board 7, a mechanical switch for each of the power button 4a and the setting button 5a, a light emitting unit 116, light emitting units 117a to 117g, and a light emitting diode (LED) constituting each of the light emitting units 118 are mounted. Has been.

  When the main body cover 2 is put on the lower case 1 (the state shown in FIG. 1), the power button 4a is disposed on the back of the power switch 4, and the setting button 5a is disposed on the back of the setting switch 5. Therefore, when the user presses the power switch 4, the power button 4 a is pressed by the power switch 4. Similarly, when the user presses the setting switch 5, the setting button 5 a is pressed by the setting switch 5. The power switch 4 can be used to turn on / off the humidifier 200. Further, the setting switch 5 can be used to perform input operations such as setting of the operation cut-off time and the reference humidity from the start to the end of the humidifying operation of the humidifier 200.

  The front side of the main body cover 2 is formed of a resin material that transmits light. Therefore, in the state of FIG. 1 where the lower case 1 is covered with the main body cover 2, when the light emitting unit 116, the light emitting units 117 a to 117 g and the light emitting unit 118 emit light, the display unit 150 of these light emitting units from the outside of the main body cover 2. The display can be visually recognized. The side surface and the rear side of the main body cover 2 are also formed of a resin material.

  As shown in FIG. 6, a steam generation device 71 is accommodated in the lower case 1. The steam generating device 71 includes an evaporating dish 71 a and a heater 72. The evaporating dish 71a has a circular dish shape with an upper opening. The evaporating dish 71a is made of, for example, a metal member. The evaporating dish 71a is a storage unit that stores water for humidification. The water stored in the evaporating dish 71 a is supplied from the water supply tank 41. The water in the water supply tank 41 is supplied from the water supply port 73 to the evaporating dish 71 a via the water supply path 74. The water supply tank 41 is covered with a water supply tank cover 3 formed of a resin material.

  The heater 72 is disposed so as to be wound around the outer periphery of the evaporating dish 71a. The heater 72 is for heating the water in the evaporating dish 71a, which is a storage unit, to generate steam. That is, when the heater 72 is energized, the water supplied to the steam generating device 71 can be heated to generate high-temperature steam.

  The steam generation device 71 is provided with the above-described steam generation device cover 75 so as to cover the upper opening. The steam generator cover 75 is made of a heat-resistant resin material. A steam vent is formed on the upper surface of the steam generator cover 75. The steam duct 51 described above is attached to the upper side of the steam generator cover 75. The steam duct 51 is provided so as to cover the steam vent on the upper surface of the steam generator cover 75. The steam duct 51 is made of a heat resistant resin material. In the upper part of the steam duct 51, a delivery port 52 opened forward is formed.

  A fan chamber 64 is formed behind the steam generating device 71 in the lower case 1. A blower fan 62 is disposed in the fan chamber 64. The rotation of the blower fan 62 is driven by a motor 62a. The rotation axis of the blower fan 62 is arranged in parallel with the front-rear direction of the lower case 1.

  The interior of the fan chamber 64 communicates with the main body side air passage 16 formed above the fan chamber 64. A main body cover side air passage 22 is formed above the main body side air passage 16. As shown in FIG. 7, the main body cover side air passage 22 is formed in the main body cover 2. When the main body cover 2 is removed from the lower case 1, the main body cover side air passage 22 is also removed from the lower case 1 together with the main body cover 2, and the main body cover side air passage 22 is separated from the main body side air passage 16.

  As described above, the movable duct 31 is provided on the upper portion of the main body cover 2 so as to be slidable in the front-rear direction. When the movable duct 31 is moved rearward, the upper portion of the water supply tank cover 3 is suppressed by the movable duct 31. In this state, the water supply tank cover 3 cannot move upward from the main body cover 2 and is integrated with the main body cover 2. Therefore, the main body cover 2 and the water supply tank cover 3 can be removed integrally.

  As shown in FIG. 4, a main body side communication portion 19 is provided at the uppermost end portion of the main body side air passage 16 connected to the main body cover side air passage 22. An opening 19 a is formed in the main body side communication portion 19. The opening 19a is for connecting the main body cover side air passage 22 and the main body side air passage 16 so as to allow ventilation. The opening 19a is provided with a shutter 20 that opens and closes the opening 19a.

  The shutter 20 closes the opening 19a when the main body cover 2 is removed from the lower case 1, and opens the opening 19a when the main body cover 2 is attached to the lower case 1, and opens the main body side air passage 16 and the main body. The cover side air passage 22 is communicated. In this way, when the main body cover 2 is removed from the lower case 1 during maintenance of the humidifier 200, foreign matter, water, or the like enters the fan chamber 64 from the opening 19a via the main body side air passage 16. Can be suppressed.

  At least a part of the shutter 20 is disposed below the peripheral edge 19b of the main body side communication portion 19 that forms the opening 19a. One end side of the shutter 20 is rotatably supported by a shaft support portion 19 c formed in the main body side communication portion 19. A spring (not shown) is provided on the back surface of the shutter 20. This spring urges the other end side of the shutter 20 upward so as to close the opening 19a from below. The shutter 20 whose other end is urged upward is locked by coming into contact with the back surface of the peripheral edge 19 b of the main body side communication portion 19. Further, a convex portion 20 b is formed on the upper surface of the shutter 20.

  As shown in FIG. 5, a branch air passage 25 is formed adjacent to the main body cover side air passage 22. The main body cover side air passage 22 and the branch air passage 25 are partitioned by a partition plate 28. A rib 24 is formed at the lower end of the partition plate 28. The rib 24 is formed integrally with the main body cover side air passage 22. The rib 24 is an opening member that opens the shutter 20.

  A body cover side communication portion 23 is formed so as to surround the outer periphery of the lower ends of the body cover side air passage 22 and the branch air passage 25. When the main body cover 2 is attached to the lower case 1, the main body cover side communication portion 23 and the main body side communication portion 19 come into contact with each other, and the main body side air passage 16, the main body cover side air passage 22 and the branch air passage 25 are ventilated. Connected as possible. In this way, the airflow generated by the blower fan 62 is sent to the main body cover side air passage 22 and the branch air passage 25 via the main body side air passage 16.

  When the main body cover 2 is attached to the lower case 1, the rib 24 resists the biasing force of the spring 20 a and pushes down the convex portion 20 b on the upper surface of the shutter 20 to open the opening 19 a. In this manner, the main body side air passage 16 and the main body cover side air passage 22 are connected to be able to ventilate in a state where the opening 19a is opened.

  On the side of the rib 24 that contacts the convex portion 20b on the upper surface of the shutter 20, a curved surface portion 24a formed in a curved surface shape is formed. Moreover, the horizontal part 24b shape | molded by the linear shape so that the lower end of the rib 24 may be continued with the curved surface part 24a is formed. Furthermore, the side surface of the rib 24 is formed with a vertical portion 24c formed in a linear shape so as to be continuous with the curved surface portion 24a.

  In a state where the main body cover 2 is attached to the lower case 1, the branch air passage 25 is connected to the steam duct 51 through the communication port 29 so as to allow ventilation. In this state, the outlet 52 of the steam duct 51 communicates with the outlet 21 of the main body cover 2. In this manner, the humidifier 200 passes through the fan port 64, the main body side air passage 16, the branch air passage 25, the communication port 29, the steam duct 51 and the outlet 52 in this order from the suction port 15. Thus, an air passage leading to the air outlet 21 is formed. And the ventilation fan 62 produces | generates the airflow which blows off the air suck | inhaled from the suction inlet 15 from the blower outlet 21 via the said wind path.

  The air in the airflow passing through the air path is mixed with the steam generated by the steam generating device 71 in the steam duct 51. That is, the steam generating device 71 constitutes a humidifying means for humidifying the air in the airflow with steam generated by heating the water in the evaporating dish 71a, which is a reservoir, by the heater 72.

  On the other hand, the main body cover side air passage 22 after branching from the branch air passage 25 communicates with the blower opening 32 via the movable duct 31. That is, in the main body of the humidifier 200, the fan port 64, the main body side air passage 16, the main body cover side air passage 22, and the movable duct 31 are connected in this order from the suction port 15 to the air blowing port 32. One air passage is formed. The air path does not pass through the steam generation device 71 (steam duct 51). Therefore, the airflow blown out from the air blowing port 32 is not humidified.

  The airflow blown out from the blower port 32 is for guiding the airflow blown out from the delivery port 52 to deliver humid air to a position away from the delivery port 52 by a preset distance. The airflow that has passed through the main body cover side air passage 22 is sent to the movable duct 31 and blows out forward from the air blowing port 32 disposed above the air outlet 21.

  Here, the flow rate of the airflow blown out from the blower port 32 is the flow rate of the airflow blown out from the blowout port 21 as the air volume divided and sent to the main body cover side air passage 22 and the branch air passage 25 by the partition plate 28. Is set to be larger than By making the flow velocity of the airflow blown out from the blower port 32 larger than the flow velocity of the airflow blown out from the blowout port 21, the pressure of the former airflow is smaller than the latter airflow according to Bernoulli's theorem. As a result, the latter air current is attracted to the former air current, and the humid air of the latter air current can be effectively guided by the former air current.

  As described above, the air direction adjusting plate 33 is provided in the air blowing port 32, and the air direction adjusting plate 33 faces obliquely downward. Therefore, the airflow from the blower port 32 is blown out so as to suppress the humid air blown from the blower port 21 from above. For this reason, it acts so that the airflow from the blower outlet 32 containing airflow from the blower outlet 21 containing high temperature steam may be suppressed, and humidified air is efficiently conveyed to the position away from the outlet 52. Can do.

  As shown in FIG. 7, the control board 8 is disposed between the operation board 7 and the steam generation device 71 inside the lower case 1. A microcomputer (microcomputer) 100 that controls the operation of the humidifier 200 is mounted on the control board 8. In particular, the microcomputer 100 constitutes control means for controlling energization to the heater 72 and energization to the motor 62 a that drives the blower fan 62.

  A configuration of a control system including the microcomputer 100 will be described with reference to FIG. As shown in FIG. 8, the microcomputer 100 includes an input circuit 110, a CPU 120, a memory 130, and an output circuit 140. The microcomputer 100 is electrically connected to the operation board 7, a signal is input from the operation unit 180 to the input circuit 110, and a signal is output from the output circuit 140 to the display unit 150.

  In addition to signals from the operation unit 180, detection signals from the humidity sensor 160, the room temperature sensor 161, and the stored water amount detection unit 170 are also input to the input circuit 110 of the microcomputer 100. The humidity sensor 160 is humidity detection means for detecting the humidity of room air (room humidity). Specifically, the humidity sensor 160 is provided, for example, around the suction port 15 of the lower case 1.

  The room temperature sensor 161 is temperature detecting means for detecting the temperature of room air (room temperature). Similarly to the humidity sensor 160, the room temperature sensor 161 is specifically provided, for example, around the inlet 15 of the lower case 1.

  The stored water amount detection unit 170 detects the amount of water stored in the water supply tank 41. The water storage amount detection unit 170 is specifically provided around the water supply tank 41, for example. As the water storage amount detection unit 170, for example, a sensor that optically detects the water level in the water supply tank 41 can be used. Alternatively, a sensor or the like that is provided at the bottom of the water supply tank 41 and measures the weight of the water supply tank 41 can be used as the water storage amount detection unit 170.

  The CPU 120 performs predetermined processing on various signals input to the input circuit 110. Then, according to the processing result, a control signal is output from the output circuit 140 to the heater 72, the motor 62a of the blower fan 62, and the display unit 150. The contents of processing executed by the CPU 120 and data used for the processing are stored in the memory 130.

  Specifically, for example, when the power switch 4 is pressed, the power button 4 a is pressed, power is supplied from the AC power supply, the microcomputer 100 is activated, and the microcomputer 100 lights the LED of the light emitting unit 116. Further, when the setting switch 5 is operated, it is possible to set the operation cut-off time from the start to the end of the humidifying operation of the humidifier 200 corresponding to the number of times of pressing. For example, when the setting switch 5 is pressed once, the operation cut-off time is set to 1 hour, and when pressed twice, it is set to 2 hours. The light emitting units 117a to 117g change the number of lighting or the lighting color according to the number of times the setting switch 5 is pressed, and display the set operation cut-off time.

  The setting switch 5 also serves as a means for setting the reference humidity. For example, the reference humidity can be set by long pressing the setting switch 5, and the reference humidity can be set to increase from 60% to 10% each time the switch is pressed once thereafter. The set reference humidity is displayed by changing the number of lighting or lighting colors of the light emitting units according to the number of times the setting switch 5 is pressed. Then, when the operation cut-off time or the reference humidity is set and the setting switch 5 is pressed again after a certain time has elapsed, the humidifying operation is started.

  In the humidification operation, the microcomputer 100 outputs a control signal from the output circuit 140 to control energization to the heater 72 and energization to the motor 62a. At this time, the microcomputer 100 controls the heater 72 so that it takes two states, a high energization rate state and a low energization rate state. The high energization rate state is a state in which the energization rate is relatively higher than the low energization rate state. In other words, the low energization rate state is a state in which the energization rate is relatively lower than the high energization rate state.

  Here, the energization rate is a ratio of time during which power is supplied within a certain time. For example, an energization rate of 100% is a state in which an energization is always performed within a certain time, that is, an energization state described later. An energization rate of 0% is a state in which no energization is performed within a certain period of time, that is, the same state as a non-energization state described later.

  Further, the microcomputer 100 controls the energization of the motor 62a of the blower fan 62 so as to take two states, an energized state and a non-energized state.

  The humidifying operation of the humidifier 200 will be described with reference to FIGS. 9 to 12. First, FIG. 9 is a timing chart of the control of the heater 72 and the motor 62a in the humidifying operation of the humidifier 200. The uppermost graph in FIG. 9 shows a temporal change in the state of energization to the heater 72. In the graph at this stage, ON represents a power supply rate of 100%, and OFF represents a power supply rate of 0%. The power supply rate increases as it approaches ON, and the power supply rate decreases as it approaches OFF.

  The graph in the second row from the top shows the state time change of energization to the motor 62a. ON is an energized state and OFF is a non-energized state. And the graph of the lowest stage has shown the time change of the temperature of the water in the evaporating dish 71a. In addition, the time A shown in the figure is the off timer time.

  When the humidification operation is started, first, the continuous operation is performed for a preset initial continuous time B. During continuous operation, the microcomputer 100 continuously energizes the heater 72 and the motor 62a, that is, the heater 72 is always in a high energization rate state and the motor 62a is always energized.

  After continuous operation, intermittent operation is performed. In the intermittent operation, the microcomputer 100 causes the heater 72 to alternately repeat the high energization rate state and the low energization rate state. Further, the microcomputer 100 alternately repeats the energized state and the non-energized state for the motor 62a. At this time, the duration of the high energization rate state of the heater 72 is the energization time C1. And the continuation time of the low energization rate state of the heater 72 is the energization interval C2.

  Further, here, the period during which the heater 72 is in the high energization rate state and the period during which the motor 62a is in the energized state are not completely matched. That is, the microcomputer 100 sets the blower fan 62 in the energized state after the first delay time (delay time D1) has elapsed since the heater 72 was set in the high energization rate state. Then, after the elapse of the delay time D2 from the time when the heater 72 is set to the low energization rate state, the blower fan 62 is set to the non-energized state.

  Here, according to the room temperature detected by the room temperature sensor 161 which is a temperature detection means, the microcomputer 100 determines the duration of the high power supply rate state (energization time C1) and the duration of the low power supply rate state (energization interval C2). Change at least one. In particular, when attention is paid to two indoor temperature values (the first temperature and the second temperature), the following expression can be used. That is, the microcomputer 100 firstly has the duration of the high energization rate state (energization time C1) and the duration of the low energization rate state (when the room temperature detected by the room temperature sensor 161 serving as the temperature detection means is the first temperature). The first control is performed for the energization interval C2). When the room temperature detected by the room temperature sensor 161, which is a temperature detecting means, is a second temperature different from the first temperature, the microcomputer 100 continues the high energization rate state (energization time C1) and the low energization rate state. At least one of the continuation time (energization interval C2) performs the second control different from the first control.

  At this time, the microcomputer 100 may also change the first delay time (delay time D1) according to the room temperature detected by the room temperature sensor 161 serving as the temperature detection means. Further, the microcomputer 100 may change the delay time D2 in accordance with the room temperature detected by the room temperature sensor 161 serving as a temperature detection unit.

  Changes in the duration (energization time C1) of the high energization rate state and the duration (energization interval C2) of the low energization rate state, the first delay time (delay time D1) and the delay time D2 according to the room temperature Will be described with reference to FIG. FIG. 10A is an example, and FIG. 10B is another example. More specifically, (a) is an example in which each time and interval is linearly changed according to the room temperature, and (b) is an example in which each time and interval is changed stepwise according to the room temperature.

  Thus, in any of these examples (a) and (b), the microcomputer 100 increases the duration C1 of the high energization rate state as the room temperature detected by the room temperature sensor 161 is lower. In other words, when the second temperature is lower than the first temperature, the microcomputer 100 makes the duration C1 of the high energization rate state in the second control longer than that in the first control.

  Further, the microcomputer 100 shortens the duration C2 of the low energization rate state as the room temperature detected by the room temperature sensor 161 is lower. In other words, when the second temperature is lower than the first temperature, the microcomputer 100 shortens the duration of the low energization rate state in the second control as compared with the first control.

  In addition, in the example in which each time and interval in (b) is changed step by step, when the difference between the two temperature values of the first temperature and the second temperature is small, the high energization rate even if the temperature is changed. There may be a case where the state duration C1 or the like does not change. Therefore, if expressed more accurately with respect to the second control, the second control has a second temperature in which the room temperature detected by the room temperature sensor 161 is different from the first temperature by “a predetermined temperature or more”. In this case, it can be said that the control is such that at least one of the duration C1 in the high energization rate state and the duration C2 in the low energization rate state is different from the first control.

  By doing so, particularly when the room temperature is low, when the heating by the heater 72 is temporarily stopped or weakened, the temperature of the humidifying water greatly decreases and the heating by the heater 72 is resumed. It can suppress that it takes time until steam is emitted. And while reducing the time which restarts steam | vapor generation | occurrence | production, a moisturizing effect suppresses a fall, it can also suppress that the time which only the cold wind which is not humidified blows off shortens or eliminates and gives a user discomfort.

  Further, the microcomputer 100 increases the first delay time (delay time D1) as the room temperature detected by the room temperature sensor 161 is lower. By energizing the blower fan 62 after the first delay time (delay time D1) has elapsed from the time when the heater 72 is set to the high energization rate state, the water temperature decreases while the heater 72 is in the low energization rate state. It is possible to prevent only cold wind from blowing out after the restart until steam is generated, thereby improving comfort. At this time, as the room temperature detected by the room temperature sensor 161 is lower, the first delay time (delay time D1) is lengthened, so that the first delay time (delay time D1) is adjusted in accordance with the drop in water temperature due to room temperature. By adjusting, it can suppress that only cold wind blows out more effectively, and can improve comfort.

  Further, in these examples, the microcomputer 100 increases the delay time D2 as the room temperature detected by the room temperature sensor 161 is lower. Vapor collected in the space above the evaporating dish 71a immediately after the heater 72 is set to the low power supply rate state by turning off the blower fan 62 after the delay time D2 has elapsed from the time when the heater 72 is set to the low power supply rate state. Therefore, the generated steam can be used efficiently.

  Next, FIG. 11 is a timing chart when the humidifying operation control is performed using the indoor humidity. Also in the case shown in FIG. 11, the basic control in the intermittent operation is the same as that in FIG. However, in the case shown in FIG. 11, when the indoor humidity detected by the humidity sensor 160, which is a humidity detecting means, becomes equal to or higher than a preset humidity reference value F-Hi during intermittent operation, the microcomputer 100 The heater 72 is set to a low energization rate state, and the blower fan 62 is set to a non-energized state.

  After that, when the indoor humidity detected by the humidity sensor 160 becomes equal to or lower than the preset F-Lo (F-Lo <F-Hi), the microcomputer 100 again sets the heater 72 to the high power supply rate state, In addition, the blower fan 62 is turned on again. When the heater 72 is changed from the low energization rate state to the high energization rate state, the microcomputer 100 energizes the blower fan 62 after the second delay time has elapsed since the heater 72 was changed to the high energization rate state.

  By doing in this way, in order to prevent excessive humidification and to suppress dew condensation, the heater 72 and the blower fan 62 can be stopped. At this time, the water temperature of the evaporating dish 71a is lowered, and steam is generated when the operation is resumed. It takes a long time to suppress the reduction of the moisturizing effect and the blowing of only cold air.

  Here, the second delay time is a time obtained by adding an additional delay time E to the delay time D1 described above. Then, the microcomputer 100 may change the second delay time (D1 + E) according to the elapsed time until the heater 72 is changed from the low energization rate state to the high energization rate state. The elapsed time until the heater 72 is changed from the low energization rate state to the high energization rate state is the time indicated as the humidification stop time in FIG. As can be seen from the figure, this humidification stop time is equal to the time from when the indoor humidity becomes equal to or higher than F-Hi until it decreases to F-Lo or lower. In this case, it is better to increase the second delay time (D1 + E) as the humidification stop time is longer.

  Since the drop in water temperature in the evaporating dish 71a when humidification is stopped depends on the stop time, the moisturizing effect and comfort are improved by adjusting the second delay time (D1 + E) during re-operation according to the stop time. However, it is possible to prevent excessive steam from being excessively humidified.

  Further, the microcomputer 100 may change the second delay time (D1 + E) according to the room temperature detected by the room temperature sensor 161. In this case, it is better to lengthen the second delay time (D1 + E) as the room temperature is lower. In the above-described control, the second delay time (D1 + E) is preferably changed by changing the additional delay time E.

  Since the drop in the water temperature in the evaporating dish 71a when the humidification is stopped depends on the room temperature, the moisturizing effect and comfort can be improved by adjusting the second delay time (D1 + E) during re-operation according to the room temperature. On the other hand, it is possible to prevent excessive steam from being excessively humidified.

  In the above, regarding the energization control to the heater 72, the case where the high energization rate state is set to 100% and the low energization rate state is set to 0% is described. However, if there is a relative level difference in the energization rate between the high energization rate state and the low energization rate state, the specific value of the energization rate is not limited to these. For example, FIG. 12 is an example in which the energization rate in the low energization rate state is set to a value different from 0% so that the energization to the heater 72 is not completely stopped even in the low energization rate state.

  By doing in this way, since the water temperature of the evaporating dish 71a becomes difficult to fall compared with the case where the energization rate to the heater 72 is set to 0% (completely stopped), the amount of water temperature decreases due to the difference in room temperature or humidification stop time. The effect of. Therefore, since it becomes easy to start ventilation according to the production | generation start of a vapor | steam, a moisturizing effect can be heightened efficiently using a vapor | steam. In addition, energization of the blower fan 62 is started before steam is generated, and it is possible to suppress only cold wind from blowing out, and comfort can be improved.

  Further, the energization rate in the low energization rate state may be changed according to the room temperature detected by the room temperature sensor 161. At this time, the lower the room temperature, the higher the energization rate can further reduce the impact on the water temperature drop due to the difference in room temperature, and more efficient use of steam to enhance the moisturizing effect and only cold wind blows out. This can be suppressed and comfort can be improved. The same applies to the high energization rate state.

  In order to perform the control with the elapsed time measurement as described above, the microcomputer 100 may be provided with a timer (timer) for measuring the elapsed time.

Next, the flow of the humidifying operation of the humidifier 200 configured as described above will be described once again with reference to the flowchart of FIG.
First, the user of the humidifier 200 connects the power cord to the power cord connecting portion 17 and presses the power switch 4. Then, the power button 4 a is pressed and power is supplied to the microcomputer 100. When the microcomputer 100 is activated, the microcomputer 100 commands the LED of the light emitting unit 116 to emit light via the output circuit 140 and enters a state of waiting for an input operation of the setting switch 5.

  The user operates the setting switch 5 to set the operation cut-off time from the start of the humidifying operation of the humidifier 200 to the end thereof. When the setting switch 5 is pressed, the setting button 5 a is pressed, and an operation signal for the setting button 5 a is input to the microcomputer 100 via the input circuit 110. The microcomputer 100 sets the off timer time A in accordance with the input operation signal (step S1). The set off timer time A is stored in the memory 130. The turn-off timer time A is an operation cut-off time from the start of the humidification operation to the end. For example, 8 hours is set as the off timer time A. Then, when the user presses the setting switch 5 again after a predetermined time has elapsed, the humidifying operation is started. When the humidifying operation is started, the process proceeds to step S2.

  In step S <b> 2, the microcomputer 100 determines whether the time measured by the timer of the microcomputer 100 after starting operation has passed a preset initial continuous time B. When the elapsed time from the start of operation does not reach the initial continuous time B, the continuous humidification operation is continued, and the determination in step S2 is repeated. When the initial continuous time B has elapsed from the start of operation, the process proceeds to step S3.

  In step S3, the humidity sensor 160 detects the room humidity, and the room temperature sensor 161 detects the room temperature. Moreover, the microcomputer 100 calculates the time (humidification stop time) during which humidification is stopped immediately before step S3 (the latest past). Then, the process proceeds to step S4.

  In step S4, the microcomputer 100 sets the energization time C1, the energization interval C2, the delay time D1, and the delay time D2 based on the room temperature detected in step S3. Further, the microcomputer 100 sets the additional delay time E based on the room temperature detected in step S3 and the humidification stop time calculated in step S3. Then, the microcomputer 100 starts an intermittent operation for intermittently energizing the heater 72 and the motor 62a based on the set times C1, C2, D1, D2, and E. In the intermittent operation, as described above, the heater 72 repeats the high energization rate state and the low energization rate state, and the motor 62a repeats the energization state and the non-energization state. Then, the process proceeds to step S5.

  In step S5, the microcomputer 100 determines whether or not the room humidity detected in step S3 is smaller than the humidity reference value F-Hi. If the room humidity is lower than F-Hi, the process proceeds to step S6.

  In step S6, the microcomputer 100 determines whether or not the timer time A has elapsed since the time counted by the timer after starting the humidifying operation. If the cut-off timer time A has not yet elapsed since the start of the humidification operation, the process returns to step S3 and the humidification operation is continued. When the cut-off timer time A has elapsed since the start of the humidification operation, the process proceeds to step S7, and the microcomputer 100 stops the humidification operation. That is, the microcomputer 100 stops energization to the heater 72 and the motor 62a. And a series of operation | movement flows are complete | finished.

  On the other hand, if the room humidity is F-Hi or higher in step S5, the process proceeds to step S8. In step S8, the microcomputer 100 stops the humidification operation by setting the heater 72 in the low energization rate state and the motor 62a in the non-energization state. Then, the process proceeds to step S9.

  In step S <b> 9, the microcomputer 100 determines whether or not the timer time A has elapsed since the time counted by the timer after starting the humidifying operation. When the cut-off timer time A has elapsed since the start of the humidifying operation, the operation is stopped while the humidifying operation is stopped, and the series of operation flows ends. On the other hand, if the cut-off timer time A has not yet elapsed since the humidification operation was started, the process proceeds to step S10.

  In step S10, indoor humidity is detected by the humidity sensor 160, and the microcomputer 100 determines whether or not the detected indoor humidity is equal to or lower than F-Lo. When indoor humidity is not below F-Lo, it returns to step S8 and continues the state of a humidification stop. On the other hand, when the room humidity is equal to or lower than F-Lo, the process proceeds to step S6. If the cut-off timer time A has not elapsed in step S6, humidification (intermittent operation) is resumed in step S4 after setting in step S3.

  The humidifier configured as described above includes the lower case 1, the main body cover 2 and the water supply tank cover 3, which are the main body in which the suction port 15 and the air outlet 21 are formed, and the air sucked from the air inlet 15. And a heater 72 for generating steam by heating the water in the evaporating dish 71a and humidifying the air in the airflow with the generated steam. And a microcomputer 100 for controlling energization to the heater 72 and energization to the motor 62a for driving the blower fan 62, and a room temperature sensor 161 for detecting the room temperature. In addition, the microcomputer 100 alternately repeats the high energization rate state and the low energization rate state where the energization rate is lower than the high energization rate state for the heater 72.

  Then, the microcomputer 100 changes at least one of the duration of the high energization rate state and the duration of the low energization rate state according to the room temperature detected by the room temperature sensor 161. In other words, when the room temperature detected by the room temperature sensor 161 is the first temperature, the microcomputer 100 performs the first control on the duration time in the high current supply rate state and the duration time in the low current conduction rate state, and the room temperature sensor 161. When the indoor temperature detected by the second temperature is a second temperature that differs from the first temperature by a predetermined temperature or more, at least one of the duration of the high energization rate state and the duration of the low energization rate state is the first control. A different second control is performed.

  For this reason, it is possible to efficiently and appropriately generate steam according to the degree of temperature change of the steam generating water during intermittent operation of the heater that heats the steam generating water. That is, even during intermittent operation of the heater, steam can be efficiently generated, the total amount of steam generated can be maintained in an appropriate range, and the moisturizing effect can be maintained. Therefore, it is possible to provide a humidifier with high comfort while transporting high-humidity air to the position where the user is present and maintaining the moisturizing effect.

Embodiment 2. FIG.
FIGS. 14 to 16 relate to the second embodiment of the present invention, FIG. 14 is a block diagram of a control system of the humidifier, FIG. 15 is a diagram for explaining the operation of the humidifier, and FIG. 16 is an operation of the humidifier. FIG.
In the second embodiment described here, the temperature of the water stored in the evaporating dish 71a is detected in the first embodiment, and the motor 62a of the blower fan 62 is detected according to the detected water temperature of the evaporating dish 71a. The current supply is controlled.

  That is, as shown in FIG. 14, in the second embodiment, a water temperature sensor 162 is provided. The water temperature sensor 162 is a water temperature detection means for detecting the temperature of the water stored in the evaporating dish 71a that is a storage unit. The water temperature sensor 162 is disposed inside the evaporating dish 71a. Alternatively, the evaporating dish 71a may be made of a material having high thermal conductivity such as iron, and the water temperature sensor 162 may be arranged so as to detect the temperature of the evaporating dish 71a from the outside of the evaporating dish 71a. By doing in this way, the temperature of the water in the evaporating dish 71a can be accurately detected, and it is not necessary to provide a sensor inside the evaporating dish 71a, so that the sealing property (water tightness) of the evaporating dish 71a is ensured. It becomes easy.

  The detection signal of the water temperature sensor 162 is input to the input circuit 110 of the microcomputer 100. The microcomputer 100 serving as a control unit also controls energization of the motor 62 a of the blower fan 62 using the input detection signal of the water temperature sensor 162.

  FIG. 15 is a timing chart at the time of humidifying operation control in the second embodiment. As in the first embodiment, during intermittent operation, the microcomputer 100 controls the heater 72 so as to repeat the high energization rate state and the low energization rate state, and the motor 62a repeats the energization state and the non-energization state. To control.

  At this time, in the first embodiment, the motor 72a is energized after the first delay time (delay time D1) has elapsed after the heater 72 is in the high energization rate state. On the other hand, in the second embodiment, the control using the first delay time (delay time D1) is not performed, but the motor 62a is energized using the water temperature detected by the water temperature sensor 162 instead. Control.

  Specifically, the microcomputer 100 sets the motor 62a in the energized state when the water temperature detected by the water temperature sensor 162 becomes equal to or higher than the preset water temperature reference value T1 after the heater 72 is set in the high energization rate state. . Here, the water temperature reference value T1 is preferably set to a temperature at which steam starts to be generated from the water in the evaporating dish 71a.

  Here, when the energization time C1 has elapsed since the heater 72 was set in the high energization rate state, the heater 62 is set in the low energization rate state and at the same time the motor 62a is deactivated. As a result, the duration during which the motor 62a is energized is C1 '. As in the first embodiment, the motor 62a may be in a non-energized state after the delay time D2 has elapsed since the heater 72 was set in a low energization rate state. Alternatively, when the water temperature detected by the water temperature sensor 162 is lower than the water temperature reference value T1, the motor 62a may be turned off.

  Next, the flow of the humidifying operation of the humidifier 200 configured as described above will be described once again with reference to the flowchart of FIG.

  When the user operates the setting switch 5 to perform an operation for setting the operation cut-off time of the humidifier 200, the microcomputer 100 sets the turn-off timer time A according to the input operation signal. The microcomputer 100 also sets an initial continuous time B (step S11). The set off timer time A and initial continuous time B are stored in the memory 130. Then, when the user presses the setting switch 5 again after a predetermined time has elapsed, the humidifying operation is started. When the humidifying operation is started, the process proceeds to step S12.

  Step S12 is the same as step S2 in FIG. In step S13, the room temperature sensor 161 detects the room temperature. Further, the microcomputer 100 sets the energization time C1 and the energization interval C2 based on the detected room temperature. Then, the process proceeds to step S14.

  In step S <b> 14, the microcomputer 100 puts the heater 72 in a high energization rate state and starts energizing the heater 72. Then, the process proceeds to step S15. In step S15, the water temperature sensor 162 detects the water temperature in the evaporating dish 71a. Then, the microcomputer 100 determines whether or not the detected water temperature is equal to or higher than the water temperature reference value T1. If the detected water temperature is not equal to or higher than the water temperature reference value T1, the process waits while repeating the determination in step S15. If the detected water temperature is equal to or higher than the water temperature reference value T1, the process proceeds to step S16.

  In step S16, the microcomputer 100 energizes the heater 72 and starts energizing the motor 62a. Then, the process proceeds to step S17. In step S17, the indoor humidity is detected by the humidity sensor 160, and the microcomputer 100 determines whether or not the detected indoor humidity is smaller than the humidity reference value F-Hi. If the indoor humidity is lower than F-Hi, the process proceeds to step S18.

  In step S18, the microcomputer 100 determines whether or not the time counted by the timer has passed the energization time C1 since the heater 72 is set in the high energization rate state in step S14. If the energization time C1 has not elapsed since the heater 72 was set in the high energization rate state, the process waits while repeating the determination in step S18, and if the energization time C1 has elapsed since the heater 72 was set in the high energization rate state, the step Proceed to S19.

  In step S <b> 20, the microcomputer 100 determines whether or not the timer time A has elapsed since the time counted by the timer after starting the humidifying operation. If the cut-off timer time A has not yet elapsed since the start of the humidifying operation, the process returns to step S13 and the humidifying operation is continued. When the cut timer time A has elapsed since the start of the humidifying operation, the process proceeds to step S21, and the microcomputer 100 stops the humidifying operation. That is, the microcomputer 100 stops energization to the heater 72 and the motor 62a. And a series of operation | movement flows are complete | finished.

  On the other hand, if the room humidity is F-Hi or higher in step S17, the process proceeds to step 22. In step S22, the microcomputer 100 sets the heater 72 to a low energization rate state and sets the motor 62a to a non-energization state to stop the humidification operation. Then, the process proceeds to step S23.

  In step S <b> 23, the microcomputer 100 determines whether or not the timer time A has elapsed since the time counted by the timer after starting the humidifying operation. When the cut-off timer time A has elapsed since the start of the humidifying operation, the operation is stopped while the humidifying operation is stopped, and the series of operation flows ends. On the other hand, if the cut-off timer time A has not yet elapsed since the humidification operation was started, the process proceeds to step S24.

In step S24, the indoor humidity is detected by the humidity sensor 160, and the microcomputer 100 determines whether or not the detected indoor humidity is equal to or lower than F-Lo. When indoor humidity is not below F-Lo, it returns to step S22 and the state of a humidification stop is continued. On the other hand, if the indoor humidity is equal to or lower than F-Lo, the process proceeds to step S20. If the cut-off timer time A has not elapsed in step S20, energization to the heater 72 is resumed in step S14 after the setting in step S13.
Other configurations and operations are the same as those in the first embodiment, and detailed description thereof is omitted.

  The humidifier configured as described above can achieve the same effects as those of the first embodiment, and can also start blowing in accordance with the start of generation of steam accurately. The effect can be enhanced. Further, energization of the blower fan 62 is started before the steam is generated, so that it is possible to suppress only cold wind from blowing out, and comfort can be improved.

  DESCRIPTION OF SYMBOLS 1 Lower case, 2 Body cover, 3 Water supply tank cover, 4 Power switch, 4a Power button, 5 Setting switch, 5a Setting button, 7 Operation board, 8 Control board, 11 Display operation part, 15 Suction port, 16 Body side wind Road, 17 power cord connection part, 19 main body side communication part, 19a opening, 19b peripheral edge, 19c shaft support part, 20 shutter, 20b convex part, 21 air outlet, 22 main body cover side air passage, 23 main body cover side communication part, 24 Rib, 24a Curved portion, 24b Horizontal portion, 24c Vertical portion, 25 Branch air passage, 28 Partition plate, 29 Communication port, 31 Movable duct, 32 Air outlet, 33 Air direction adjusting plate, 41 Water supply tank, 51 Steam duct, 52 Outlet, 62 blower fan, 62a motor, 64 fan chamber 71 Steam generating device, 71a Evaporating dish, 72 Heater 73 Water supply port, 74 Water supply path, 75 Steam generating device cover, 100 Microcomputer, 110 Input circuit, 120 CPU, 130 Memory, 140 Output circuit, 150 Display unit, 160 Humidity sensor 161 Room temperature sensor, 162 Water temperature sensor, 170 Water storage amount detection unit, 180 Operation unit, 200 Humidifier

In the humidifier according to the present invention, a main body in which an inlet and an outlet are formed, an air blowing fan that generates an airflow that blows out air sucked from the inlet from the outlet, a storage unit that stores water, and the above A heater that heats the water in the reservoir and generates steam; humidifying means that humidifies the air in the airflow with the generated steam; energizing the heater and energizing the motor that drives the blower fan A control means for controlling the temperature, a temperature detection means for detecting the room temperature, and a humidity detection means for detecting the room humidity , wherein the control means is energized with respect to the heater from a high power supply rate state and the high power supply rate state. When the room temperature detected by the temperature detection means is the first temperature, the duration of the high energization rate state and the duration of the low energization rate state are alternately repeated. For performing a first control, the temperature sensing means and the first duration of the high current rate state when the room temperature detected is the first predetermined constant temperature or higher than the temperature lower second temperature by There second row control for longer than control, the motor was repeated alternately energized and de-energized states for said from the point of the heater to the high duty factor state after a first delay time The first delay time is increased as the indoor temperature detected by the temperature detection unit is lowered, and the indoor humidity detected by the humidity detection unit is equal to or higher than a preset humidity reference value. And when the heater is in the low energization rate state, and the blower fan is in the non-energization state, and the heater is changed from the low energization rate state to the high energization rate state, The blower fan the serial heater from the time of the high duty factor state after a long second delay time than the first delay time is configured to the energized state.
Alternatively, the main body in which the suction port and the air outlet are formed, the blower fan that generates the airflow that blows out the air sucked from the air inlet from the air outlet, the storage unit that stores water, and the water in the storage unit are heated. And a heater for generating steam, humidifying means for humidifying the air in the airflow with the generated steam, control means for controlling energization to the heater and motor to drive the blower fan, A temperature detection means for detecting the room temperature; and a humidity detection means for detecting the room humidity, wherein the control means is a high conduction ratio state for the heater and a low conduction ratio state in which the conduction ratio is lower than the high conduction ratio state. Are alternately repeated, and when the indoor temperature detected by the temperature detecting means is the first temperature, the first control is performed for the duration of the high current-carrying rate state and the duration of the low current-carrying rate state A second period of time in which the duration of the low energization rate state is shorter than that of the first control when the room temperature detected by the temperature detection unit is a second temperature that is lower than the first temperature by a predetermined temperature or more. Performing the control, alternately repeating the energized state and the non-energized state for the motor, setting the blower fan to the energized state after elapse of a first delay time from the time when the heater is in the high energization rate state, The lower the indoor temperature detected by the temperature detecting means, the longer the first delay time is. When the indoor humidity detected by the humidity detecting means is equal to or higher than a preset humidity reference value, the heater is When the low current-carrying rate state is set, the blower fan is turned off, and the heater is changed from the low current-carrying rate state to the high current-carrying rate state, the heater is turned on. The blower fan and configured to the energized state after a long second delay time than the first delay time from the time of the state.

Alternatively, in the humidifier according to the present invention, a main body in which an inlet and an outlet are formed, a blower fan that generates an airflow that blows out air sucked from the inlet and the outlet, and a reservoir that stores water And a heater for heating the water in the reservoir to generate steam, humidifying means for humidifying the air in the airflow with the generated steam, and energizing the heater and a motor for driving the blower fan Control means for controlling the energization of the heater, temperature detecting means for detecting the indoor temperature, and humidity detecting means for detecting the indoor humidity , wherein the control means has a high energization rate state and a high energization rate state for the heater. were alternately repeated between a state of lower duty ratio low duty factor, the more the indoor temperature is low it is detected by said temperature detecting means, a longer duration of the high power factor state, the motor Nitsu Then, the energized state and the non-energized state are alternately repeated, and after the first delay time has elapsed from the time when the heater is set to the high energization rate state, the air blowing fan is set to the energized state and detected by the temperature detecting means. The lower the indoor temperature, the longer the first delay time, and when the indoor humidity detected by the humidity detecting means is equal to or higher than a preset humidity reference value, the heater is set to the low energization rate state, And when making the said ventilation fan into the said non-energized state and making the said heater into the said high energization rate state from the said low energization rate state, it is longer than said 1st delay time from the time of making the said heater into the said high energization rate state. The blower fan is placed in the energized state after the second delay time has elapsed .
Alternatively, the main body in which the suction port and the air outlet are formed, the blower fan that generates the airflow that blows out the air sucked from the air inlet from the air outlet, the storage unit that stores water, and the water in the storage unit are heated. And a heater for generating steam, humidifying means for humidifying the air in the airflow with the generated steam, control means for controlling energization to the heater and motor to drive the blower fan, A temperature detection means for detecting the room temperature; and a humidity detection means for detecting the room humidity, wherein the control means is a high conduction ratio state for the heater and a low conduction ratio state in which the conduction ratio is lower than the high conduction ratio state. The lower the indoor temperature detected by the temperature detection means, the shorter the duration of the low energization rate state, and alternately repeating the energized state and the non-energized state for the motor. The first delay is reduced as the indoor temperature detected by the temperature detection means is lowered after the lapse of a first delay time from the time when the heater is brought into the high energization state. When the indoor humidity detected by the humidity detection means is equal to or higher than a preset humidity reference value, the heater is set in the low energization rate state and the blower fan is set in the non-energized state. When the heater is changed from the low current supply rate state to the high current supply rate state, the blower fan after a lapse of a second delay time longer than the first delay time from the time when the heater is changed to the high current supply rate state. Is configured to be in the energized state.

Claims (10)

A main body formed with an inlet and an outlet;
A blower fan that generates an airflow that blows out the air sucked from the inlet through the outlet;
A humidifying means for humidifying the air in the airflow with the generated steam, having a storage section for storing water and a heater for generating water by heating the water in the storage section;
Control means for controlling energization to the heater and energization to a motor for driving the blower fan;
Temperature detecting means for detecting the room temperature,
The control means includes
For the heater, alternately repeating a high energization rate state and a low energization rate state with a lower energization rate than the high energization rate state,
When the indoor temperature detected by the temperature detecting means is the first temperature, the first control is performed for the duration of the high energization rate state and the duration of the low energization rate state, and the room detected by the temperature detecting means In the case where the temperature is a second temperature different from the first temperature by a predetermined constant temperature or more, at least one of the duration of the high energization rate state and the duration of the low energization rate state is different from the first control. Humidifier that performs control of 2.   2. The control unit according to claim 1, wherein, when the second temperature is lower than the first temperature, the control unit makes the duration of the high energization rate state in the second control longer than that of the first control. Humidifier.   2. The control unit according to claim 1, wherein, when the second temperature is lower than the first temperature, the duration of the low energization rate state in the second control is shorter than that of the first control. 2. A humidifier according to 2. The control means includes
Alternately repeating the energized state and the non-energized state for the motor,
After the elapse of a first delay time from the time when the heater is in the high energization state, the air blowing fan is set in the energization state,
The humidifier according to any one of claims 1 to 3, wherein the first delay time is increased as the indoor temperature detected by the temperature detection means is lower. Humidity detection means to detect indoor humidity,
The control means includes
When the indoor humidity detected by the humidity detection means is equal to or higher than a preset humidity reference value, the heater is set to the low energization rate state, and the blower fan is set to the non-energized state,
5. When the heater is changed from the low energization rate state to the high energization rate state, the blower fan is changed to the energization state after a second delay time has elapsed since the heater was changed to the high energization rate state. Humidifier as described in.   The humidifier according to claim 5, wherein the control unit changes the second delay time according to an elapsed time until the heater is changed from the low energization rate state to the high energization rate state.   The humidifier according to claim 5, wherein the control unit changes the second delay time according to a room temperature detected by the temperature detection unit. A main body formed with an inlet and an outlet;
A blower fan that generates an airflow that blows out the air sucked from the inlet through the outlet;
A humidifying means for humidifying the air in the airflow with the generated steam, having a storage section for storing water and a heater for generating water by heating the water in the storage section;
Control means for controlling energization to the heater and energization to a motor for driving the blower fan;
Temperature detecting means for detecting the room temperature,
The control means includes
For the heater, alternately repeating a high energization rate state and a low energization rate state with a lower energization rate than the high energization rate state,
A humidifier that changes at least one of the duration of the high energization rate state and the duration of the low energization rate state according to the room temperature detected by the temperature detection means.   The humidifier according to claim 8, wherein the control means lengthens the duration of the high energization rate state as the indoor temperature detected by the temperature detection means is lower.   The humidifier according to claim 8 or 9, wherein the control means shortens the duration of the low power supply rate state as the indoor temperature detected by the temperature detection means is lower.

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