JP7117203B2 - humidifier - Google Patents

Description

The present invention relates to humidifiers.

2. Description of the Related Art Humidifiers having a humidifying mechanism for imparting water in a water storage container to the air are conventionally known. Some of such humidifiers are equipped with a water level detection sensor capable of detecting the amount of water in the water reservoir.

For example, an air purifier with a humidifying function disclosed in Patent Document 1 has a liquid level sensor 10 as a water amount detecting means arranged on the side surface of the water storage container 6 . In this configuration, for example, the output voltage of the liquid level sensor 10 is 5V when the water level of the reservoir 6 is 4 liters. As the main body 1 of the air purifier with humidifying function is operated, the amount of water in the water storage container 6 decreases, and the output voltage of the liquid level sensor 10 also changes linearly according to the water amount level. Water volume can be detected.

JP 2012-77940 A

However, if the liquid level sensor fails for some reason, it may not be possible to accurately detect the amount of water in the reservoir.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a humidifier capable of suppressing erroneous detection by a sensor that detects the water level in a water storage container.

A humidifier according to one aspect of the present invention includes a water storage container, a humidification mechanism that releases water in the water storage container into the air, a distance sensor that detects the water level of the water storage container, and detection by the distance measurement sensor. a control unit that determines that the range sensor is abnormal when the amount of decrease in the water level of the water storage container per unit time determined from the determined water level is less than a predetermined value.

A humidifier according to another aspect of the present invention includes a water storage container, a humidification mechanism that releases water in the water storage container into the air, a distance sensor that detects the water level of the water storage container, and the distance measurement sensor. measures the water level of the water storage container a plurality of times, and determines that the distance measuring sensor is abnormal when the ratio of the effective distance data to the measured data is 0.5 or less.

According to the humidifier according to one aspect of the present invention, erroneous detection by the sensor that detects the water level in the water storage container can be suppressed.

1 is a perspective view showing an external configuration of an air purifier according to one embodiment of the present invention; FIG. It is a cross-sectional schematic diagram which shows the internal structure of the air cleaner shown in FIG. 2 is a block diagram showing the internal configuration of the air cleaner shown in FIG. 1; FIG. It is a schematic diagram which shows the structure of the lower surface of a ranging sensor. 2 is a flowchart showing a procedure of water level notification control in the air purifier shown in FIG. 1; 2 is a flow chart showing a procedure for detecting contamination of a distance measuring sensor in the air purifier shown in FIG. 1; It is a graph which shows the relationship between the rotation speed of the blower of an air cleaner, and the amount of humidification (the amount of water used). FIG. 11 is a schematic diagram showing a water storage tray and a distance measuring sensor provided in the air cleaner according to the third embodiment; FIG. 9 is a diagram showing a histogram when the distance from the water storage tray 20 to the water surface is measured using the distance measuring sensor shown in FIG. 8; This figure shows the measurement results when the distance measuring sensor is clean. FIG. 9 is a diagram showing a histogram when the distance from the water storage tray 20 to the water surface is measured using the distance measuring sensor shown in FIG. 8; This figure shows the measurement results when the distance measuring sensor is dirty.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are given the same reference numerals. Their names and functions are also the same. Therefore, a detailed description thereof will not be repeated.

[First Embodiment]
In this embodiment, a humidified air purifier (a humidifier having an air purifying function), which is an example of the humidifier of the present invention, will be described as an example. However, in another aspect of the present invention, the humidifier is not limited to a humidifier having an air cleaning function, and can be implemented as a device having only a humidifying function. Moreover, the present invention can also be applied to an air conditioner having a humidifying function.

(Configuration of air purifier)
First, the overall configuration of a humidified air cleaner 1 (hereinafter simply referred to as air cleaner 1) according to the present embodiment will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is a perspective view of the air cleaner 1. FIG. FIG. 2 shows the internal configuration of the air cleaner 1. As shown in FIG.

As shown in FIG. 1 , the outer shape of the air cleaner 1 is formed by a housing 10 . The housing 10 includes a front portion 10a, a rear portion 10b, a top portion 10c, a side portion 10d, a bottom portion 10e, and the like. When the air cleaner 1 is installed in a state of normal use, the front part 10a is positioned on the front (front) side, the back part 10b is positioned on the back side, and the top part 10c is positioned on the upper side. The front surface portion 10a is provided with an air outlet (second outlet 36). Further, the upper surface portion 10c is provided with an air outlet (the first outlet 33) and an operation section 26 (see FIG. 3).

Inside the housing 10, there are a blower 11, air ducts 31, 32, 34, an air cleaning filter (not shown), a water storage tray (water storage container) 20, an operation unit 26, a notification unit 27, a thermometer 28, a humidity A total 29 and a control unit 41 (see FIG. 3) are provided.

The blower 11 is arranged in a blowing path 31 formed inside the housing 10 . The blower 11 is controlled by the controller 41 to start/stop the operation and to control the air volume. The blower 11 draws the air in the room where the air purifier 1 is installed into the housing 10 from the rear portion 10b and blows it out from the outlets 33 and 36 to form an air flow (wind). In FIG. 2, the flow of air inside the housing 10 is indicated by dashed arrows.

Thereby, the indoor air circulates through the air cleaner 1 . The air taken into the housing 10 first passes through an air cleaning filter (not shown) arranged on the back side 10b side, and then passes through the water storage tray 20 arranged at the bottom of the housing 10. pass. A humidification filter (humidification mechanism) 21 is provided in the water storage tray 20 . As a result, the air passing through the water storage tray 20 is humidified. The humidified air is sent out by the air blower 11 from the outlets 33 and 36 positioned above.

The airflow paths 31, 32, and 34 are formed inside the housing 10, and the wind generated by the blower 11 passes through them. The air passage 31 is formed from the bottom to the center of the housing 10 . An air cleaning filter (not shown) is arranged on the back side of the air duct 31 . A blower 11 is arranged in the blowing path 31 .

The upper air passage 32 is located above the air passage 31 . A first outlet 33 is provided on the most downstream side of the upper air passage 32 . That is, the upper air passage 32 is an air passage that guides the air generated by the blower 11 to the first outlet 33 provided in the upper surface portion 10c.

The front air passage 34 is located on the upper front side of the air passage 31 . A second outlet 36 is provided on the most downstream side of the front air passage 34 . That is, the front air passage 34 is an air passage that guides the wind generated by the blower 11 to the second outlet 36 provided in the front portion 10a.

A wind direction plate 17 is rotatably attached to the first outlet 33 . A wind direction plate 18 is attached to the second outlet 36 in a rotatable state. The opening and closing of each wind direction plate 17 and 18 is controlled by the controller 41 .

The air cleaning filter is arranged, for example, on the rear side inside the housing 10 . The air purifying filter has a fine mesh structure, and removes allergens such as dust and pollen contained in the air taken into the air purifier 1, fine particulate matter that causes air pollution, and the like. Supplement. Also, the air purifying filter may be made of a material having a deodorizing function. After passing through the filter, the air taken in from the rear portion 10b of the housing 10 is blown out from the outlets 33, 36 through the air passages 31, 23, 34. As shown in FIG. As a result, the air taken into the air purifier 1 can be purified and discharged into the room.

The operation unit 26 is arranged, for example, on the upper surface portion 10c of the housing 10 . The user can change the operating state of the air cleaner 1 by operating the operation unit 26 .

The notification unit 27 is composed of, for example, a speaker, a display unit (for example, a display, an LED lamp, etc.). The notification unit 27 notifies the user of messages, warnings, and the like based on commands from the control unit 41 . If the notification unit 27 is a speaker, the notification is given by a voice message or a warning sound. If the notification unit 27 is a display, it displays the content of the message or warning in characters, symbols, and the like. When the notification unit 27 is an LED lamp, the notification is performed by lighting or blinking the LED lamp.

The thermometer 28 and the hygrometer 29 are attached, for example, in the vicinity of the air intake port inside the housing 10 . Thermometer 28 measures the temperature in the room where air cleaner 1 is installed. A hygrometer 29 measures the humidity in the room where the air cleaner 1 is installed. Information on the temperature measured by the thermometer 28 is transmitted to the control unit 41 . Humidity information measured by the hygrometer 29 is transmitted to the control unit 41 . The temperature and humidity information transmitted to the control unit 41 is used to determine whether or not the distance measuring sensor 24 is dirty, which will be described later.

The control unit 41 is connected to each component in the air cleaner 1 and controls them. The control unit 41 is arranged, for example, in an electrical component unit arranged inside the housing 10 . A memory 43, a timer 44, and the like are provided in the control unit 41 (see FIG. 3).

The memory 43 includes ROM (Read Only Memory) and RAM (Random Access Memory). The memory 43 stores an operation program and setting data of the air purifier 1 and temporarily stores the calculation result by the control unit 41 . The timer 44 measures the processing time performed in the control unit 41, the operation time of each component in the air cleaner 1, and the like, as necessary.

(Composition of humidification unit)
Next, the configuration of the humidifying unit provided in the air cleaner 1 will be described. In the present embodiment, a vaporization type humidification unit that evaporates water by blowing air from the blower 11 onto the humidification filter 21 will be described as an example. However, the humidifier according to the present invention is not limited to those having an evaporative humidification unit, and is a steam type that generates steam by heat or an ultrasonic type that atomizes water by ultrasonic vibration and releases it. It can also be applied to those having a humidifying unit.

Further, the air purifier 1 according to this embodiment has a configuration in which a water supply tank and a water storage tray are integrated for the purpose of downsizing the apparatus. With such a configuration, the user directly fills the water storage tray instead of supplying water to the water tank. As a result, it is possible to suppress an increase in the size of the device.

The water storage tray 20 is arranged on the bottom portion 10 e of the housing 10 . Water used for indoor humidification is stored in the water storage tray 20 . The water storage tray 20 can be removed from the housing 10 by being pulled out from the side portion 10d of the housing 10. As shown in FIG. The user takes out the water storage tray 20 from the housing 10 and fills the water storage tray 20 with water, for example, when the water in the water storage tray 20 is almost empty.

As another aspect, a configuration in which a water supply port and a water supply path are provided on the upper portion of the water storage tray 20 is also possible. In the case of such a configuration, the user can supply water to the water storage tray 20 by pouring water from the water supply port.

Inside the water storage tray 20, a humidification filter (humidification mechanism) 21, a distance measurement sensor 24, and the like are provided as main constituent members.

The humidifying filter 21 has a substantially cylindrical shape. The humidification filter 21 has a filter body such as a nonwoven fabric having air permeability and water absorption. The filter body is provided on the outer peripheral portion of the substantially cylindrical humidifying filter 21 .

The humidifying filter 21 has a rotating shaft 21a in the axial direction of the cylindrical body. The rotary shaft 21a is connected to a filter drive motor. The control unit 41 controls the start and stop of the operation of the filter drive motor, the number of revolutions, and the like. Thereby, the humidification filter 21 rotates in the axial direction centering on the rotating shaft 21a.

The filter body is immersed in the water in the water storage tray 20 by the rotation of the humidifying filter 21, and the water permeates the entire filter body by capillary action. As a result, the air passing through the water storage tray 20 is supplied with water from the humidification filter 21 and is humidified.

The distance measuring sensor 24 is arranged above the water storage tray 20 within the arrangement area of the water storage tray 20 . The distance measuring sensor 24 measures the distance L from the panel portion 24a provided on the lower surface of the distance measuring sensor 24 to the water surface (see FIG. 2). The ranging sensor 24 may be placed anywhere above the water surface. For example, the distance measuring sensor 24 can be arranged on the water storage tray 20 side (specifically, on the side of the water storage tray, inside the water storage tray upper lid). It is preferably installed on the 10 side.

FIG. 4 shows the lower surface of the distance measuring sensor 24. As shown in FIG. A panel portion 24 a is provided on the lower surface of the distance measuring sensor 24 . The panel section 24a is provided with a light irradiation section 51, a light receiving section 52, and the like. The light irradiation unit 51 irradiates light toward the water surface of the water storage tray 20, which is the surface to be measured. The light receiving unit 52 detects light reflected from the measurement target surface (water surface). The distance measurement sensor 24 measures the time it takes for the light emitted from the light irradiation unit 51 to be reflected by the surface to be measured and returned to the light receiving unit 52, and determines the distance L to the surface to be measured from that time. be able to.

The distance measured by the distance measuring sensor 24 is transmitted to the control section 41 . The control unit 41 determines the height (water level) of the water stored in the water storage tray 20 based on the measured distance transmitted from the distance sensor 24 . The control unit 41 can notify the user of the water level at appropriate timing. Thereby, the user can know the water level in the water storage tray 20 .

The method of notifying the water level is, for example, when the water level in the water storage tray 20 reaches or exceeds a predetermined value (eg, upper limit) or falls below a predetermined value (eg, lower limit), using a speaker. Methods of generating a voice message or audible alarm are included. As another method, it is possible to display the current water level on the display section at appropriate timing.

(Regarding the control of the water level notification of the water storage tray)
Here, a method of controlling notification of the water level of the water storage tray 20 in the air purifier 1 will be described with reference to the flowchart of FIG.

In the air purifier 1 that is powered on, the distance L measured by the distance measuring sensor 24 is always input to the control section 41 . The controller 41 determines the water level of the water storage tray 20 based on the measured distance L (step S11). Then, the control unit 41 determines whether or not the water level has risen above the water level based on the previous measurement distance (step S12). Here, if the water level has risen (YES in step S12), the process proceeds to step S13, and if the water level has not risen (NO in step S12), the process proceeds to step S15.

If the water level has risen (YES in step S12), it can be determined that the change is due to the water supply to the water storage tray 20. Therefore, the control unit 41 determines whether or not the water level after the rise is a water level at which full water notification is required. (step S13). If the water level is such that notification of full water level is required (YES in step S13), control unit 41 notifies full water level through notification unit 27 such as a speaker and a display unit (step S14).

Here, the water level at which full-water notification is required is the water level at which the water level of the water storage tray 20 is close to or exceeds the specified full-water position. Moreover, the number of water levels that require notification of full water level is not limited to one, and it is preferable to perform full water level notification step by step at a plurality of water levels.

The end timing of the full-water notification can be, for example, a predetermined time after the start of the full-water notification (for example, ringing of an alarm). Moreover, as a more preferable method, it is possible to continue the full water notification while the water supply operation is continuing and terminate the full water notification when the water supply operation ends. As a result, when the water supply operation ends, it is possible to quickly stop the alarm sound, which is annoying to the user.

The control unit 41 determines whether or not the distance measured by the distance sensor 24 is stable (vibrating). Stay informed. Then, when the distance measured by the distance measuring sensor 24 is stabilized, it is determined that the water supply has ended, and the water full notification is terminated.

Further, in the water level notification control in the air purifier 1, not only is the water full notification at the time of water supply, but also the water supply notification for prompting the user to supply water is performed when the remaining amount of water stored in the water storage tray 20 is low. Therefore, the control unit 41 also monitors whether or not the water level has decreased after the determination of the water level. That is, the control unit 41 determines whether or not the water level has fallen below the water level based on the previous measurement distance (step S15).

Here, if the water level has not fallen (NO in step S15), the process returns to step S11. On the other hand, if the water level has decreased (YES in step S15), the control unit 41 determines whether or not the water level after the decrease is a water level that requires notification of water supply (step S16).

Here, if the water level does not require notification of water supply (NO in step S16), the process returns to step S11. On the other hand, if the water level requires notification of water supply (YES in step S16), the control unit 41 performs notification of water supply through the notification unit 27 such as a speaker and a display unit (step S17).

Here, the water level at which water supply notification is required is the water level at which the water storage tray 20 is nearly empty or has become empty. Moreover, the number of water levels that require notification of water supply is not limited to one, and it is preferable to perform notification of water supply in stages at a plurality of water levels. The end timing of the water supply notification can be, for example, a predetermined time after the start of the water supply notification (for example, ringing of an alarm sound).

(Regarding the detection of dirt on the distance measuring sensor)
Next, a method for detecting dirt on the panel portion 24a of the distance measuring sensor 24 will be described. The panel portion 24a of the distance measuring sensor 24 is arranged so as to face the water surface of the water storage tray 20, which is the surface to be measured. Therefore, for example, when water is supplied, the water surface of the water storage tray 20 may rippling, causing water to splash and water droplets to adhere to the panel portion 24a. If such water droplets become scales and remain on the surface of the panel section 24a (particularly, the light irradiation section 51) to stain the surface, there is a possibility that the distance L to the water surface cannot be measured accurately.

For example, if the surface of the light irradiating section 51 is dirty, the light emitted from the light irradiating section 51 is reflected at the dirt and returns to the light receiving section 52 . Therefore, the distance measuring sensor 24 measures the distance L as the distance shorter than the actual distance to the water surface. As a result, the controller 41 determines a position higher than the actual water level of the water storage tray 20 as the water level, resulting in an error with the actual water level.

In order to suppress such erroneous detection of the distance measurement sensor 24, the control unit 41 determines whether or not the distance measurement sensor 24 is dirty while the air purifier 1 is in operation. Specifically, the controller 41 controls the amount of decrease (decrease) in the water level of the water storage tray 20 per unit time (for example, one hour) calculated from the water level detected by the ranging sensor 24 to be less than a predetermined value. If so, it is determined that the distance measuring sensor 24 is dirty.

Note that even when the air purifier 1 is in operation, if the control unit 41 determines, for example, that indoor humidification is unnecessary, the substantial humidification operation is not performed, and the water storage tray 20 water volume may not decrease. Therefore, it is preferable to determine whether the range sensor 24 is dirty only when the air purifier 1 is substantially performing the humidification operation. As a result, it is possible to improve the accuracy of determining the presence or absence of dirt on the distance measuring sensor 24 .

Further, the predetermined value that is the threshold value for determining whether the distance sensor 24 is dirty is, for example, the detection accuracy of the distance sensor 24, the indoor temperature and humidity, the rotation speed of the blower 11, the capacity of the water storage tray 20, and the etc., can be determined. For example, when the detection accuracy of the distance measuring sensor 24 is 1 mm or more, it can be determined that the distance measuring sensor 24 is dirty when the amount of decrease in the water level per unit time (1 hour) is less than 1 cm. can.

Moreover, if the air purifier 1 is equipped with a thermometer and a hygrometer for measuring the temperature and humidity in the room, the above measurements can only be made if the measured temperature and humidity in the room meet the predetermined conditions. It is preferable to determine whether the distance sensor 24 is dirty.

For example, when the indoor temperature is low (e.g., 10° C. or lower) and high humidity (e.g., 85% or higher), the humidification operation is not performed even if the air cleaner 1 is in operation, and the water storage tray 20 is It is unlikely that the water level will decrease. Therefore, in a low temperature and high humidity state, it is preferable not to judge whether the range sensor 24 is dirty based on the amount of change in the water level detected by the range sensor 24 .

When the control unit 41 determines that the distance measuring sensor 24 is dirty, the notification unit 27 notifies the user of the fact. For example, when the notification unit 27 is a speaker, a voice message is output to the effect that the distance measurement sensor 24 is dirty. At this time, in addition to the message that the distance sensor 24 is dirty, a voice message prompting cleaning of the panel portion 24a of the distance sensor 24 may be output.

FIG. 6 shows an example of the flow of processing in the control unit 41 regarding detection of dirt on the distance measuring sensor 24. As shown in FIG. When determining whether the distance measuring sensor 24 is dirty, the control unit 41 first acquires temperature information and humidity information from the thermometer 28 and the hygrometer 29 (steps S21 and S22). Subsequently, it is determined whether or not the room is currently in a low temperature and high humidity state according to the obtained temperature information and humidity information (step S23). Here, if it is determined that the room temperature is low and the humidity is high (YES in step S23), the determination of the presence or absence of dirt on the distance measuring sensor 24 is not performed, and the process ends.

On the other hand, if it is determined that the room is not in a low temperature and high humidity state (NO in step S23), the control unit 41 acquires information on the number of revolutions of the blower 11 in operation (step S24). Next, based on the obtained temperature information, humidity information, and rotational speed information, the control unit 41 determines the above-mentioned predetermined value as a threshold for determining the presence or absence of dirt on the distance measuring sensor 24 (step S25). ). Here, the predetermined value can be determined by referring to a table stored in the memory 43, for example. In this table, conditions such as indoor temperature and humidity, and the number of revolutions of the blower 11, and a plurality of different predetermined values are stored in association with each other.

After that, the control unit 41 calculates the amount of change in the distance L measured by the distance measuring sensor 24 for a predetermined period of time (for example, one hour), and calculates the amount of water level decrease per unit time of the water storage tray 20 (water level decrease amount/unit time). is determined (step S26). Then, the control unit 41 compares the obtained water level decrease amount per unit time with the determined predetermined value, and determines whether the water level decrease amount per unit time is less than the predetermined value ( step S27).

If the amount of water level decrease per unit time is equal to or greater than the predetermined value (NO in step S27), it is determined that the distance measuring sensor 24 is not soiled, and the process ends.

On the other hand, if the water level decrease amount per unit time is less than the predetermined value (YES in step S27), it is determined that the distance measurement sensor 24 is dirty. Then, the control unit 41 notifies the user to that effect through the notification unit 27 (step S28). After that, the process ends.

(Summary of the first embodiment)
As described above, the air cleaner 1 according to this embodiment includes the water storage tray 20 . The water storage tray 20 is provided with a humidification filter 21, a distance sensor 24, and the like. The distance sensor 24 measures the distance L from the water stored in the water storage tray 20 to the water surface. Thereby, the water level of the water storage tray 20 can be detected.

Then, the control unit 41 provided in the air purifier 1 measures the distance when the amount of water level decrease per unit time of the water storage tray 20 determined from the water level detected by the distance measurement sensor 24 is less than a predetermined value. It is determined that the sensor 24 is dirty.

According to the above configuration, when the change in the water level detected by the distance measuring sensor 24 is considered to be abnormal, it is determined that the distance measuring sensor 24 is dirty, and the cleaning of the distance measuring sensor 24 is urged. can be done. As a result, erroneous detection of the water level in the water storage tray 20 by the distance measuring sensor 24 can be suppressed.

For example, the water level in the water storage tray 20 is normally expected to decrease, such as when the water level detected by the distance measuring sensor 24 does not change at all even though the air cleaner 1 is performing humidification operation. If the detection water level of the distance measuring sensor 24 does not decrease in the state where the distance measuring sensor 24 is in a state where the distance measuring sensor 24 is kept clean, cleaning of the distance measuring sensor 24 can be urged. Therefore, the water level in the water storage tray 20 can be detected with higher accuracy using the distance measuring sensor 24 .

[Second embodiment]
Next, a second embodiment of the invention will be described. The air purifier 1 according to the second embodiment differs from the first embodiment in the method of determining whether the distance measuring sensor 24 is dirty. Other than that, the same configuration as in the first embodiment can be applied. Therefore, the points different from the first embodiment will be mainly described below.

In the present embodiment, as in the first embodiment, the control unit 41 controls the range sensor 24 when the amount of decrease in water level per unit time of the water storage tray 20 detected by the range sensor 24 is less than a predetermined value. 24 is determined to be dirty.

In the first embodiment, the predetermined value that is the threshold for determining whether the distance sensor 24 is dirty is, for example, the detection accuracy of the distance sensor 24, the indoor temperature and humidity, the rotation speed of the blower 11, It is determined based on the capacity of the water storage tray 20 and the like.

On the other hand, in the air purifier 1 according to the present embodiment, the predetermined value is the predicted value of the amount of water level decrease per unit time of the water storage tray 20 during humidification operation. The predicted value of the amount of water level decrease per unit time can be calculated based on the indoor temperature and humidity, the number of revolutions of the blower 11, etc. during the humidification operation of the air purifier 1. FIG.

Specifically, the predicted value of the amount of water level decrease per unit time is the indoor temperature and the indoor humidity acquired by the control unit 41 and the air blower 11 can be calculated by inputting the number of revolutions of Alternatively, the predicted value of the amount of water level decrease per unit time can be determined by referring to a table stored in the memory 43 .

An example of a method for determining the predicted value of the amount of water level decrease per unit time will be described below. Here, a method for determining the predicted value based on the number of revolutions of the blower 11 and the indoor temperature and humidity will be described. The amount of water used during the humidification operation (that is, the amount of humidification) varies depending on the humidification capacity of the humidifier.

In a general humidifier, the amount of humidification (the amount of water used) increases depending on the air volume of the blower. The air volume of the blower increases by increasing the rotation speed of the blower. FIG. 7 shows an example of the relationship between the air volume of the blower and the humidification volume.

In addition, in general humidifiers, the amount of humidification (the amount of water used) increases as the indoor temperature is higher and as the indoor humidity is lower. Table 1 below shows an example of the relationship between indoor temperature and humidity and the amount of humidification. Table 1 shows an example when the humidifier is operated in the "strong operation" mode in which the air volume of the blower is approximately 6.3 m ³ /min.

Based on the above relationship, Table 2 below shows the relationship between indoor temperature and humidity and the amount of humidification.

Table 2 shows the coefficients of the humidification capacity at various temperatures and humidity when the humidification capacity (humidification amount) when the indoor temperature/humidity is 20° C./30% is taken as the standard (=1). For example, the coefficient when the temperature/humidity is 20° C./60% is 0.5, so the amount of humidification is half that when the temperature/humidity is 20° C./30%.

From the above, the amount of water in the water storage tray 20 (that is, the amount of humidification) used when the air cleaner 1 performs the humidification operation depends on the air volume of the blower 11 (depending on the number of revolutions), and the indoor temperature and humidity. change depending on Therefore, the predicted value of the amount of water level decrease per unit time can be determined based on the air volume of the blower 11 and the indoor temperature and humidity.

For example, the air volume of the blower 11 can be obtained from information stored in the memory 43 . Then, the control unit 41 refers to the graph shown in FIG. 7 to determine the humidification amount for the acquired air volume of the blower 11 .

Subsequently, information on indoor temperature and humidity is obtained from the thermometer 28 and the hygrometer 29 . The control unit 41 refers to Table 2 and selects the coefficient for the obtained temperature and humidity. Then, the amount of humidification obtained from the graph shown in FIG. 7 is multiplied by the selected coefficient to determine the predicted value of the amount of decrease in water amount per unit time. The predicted values obtained here are obtained in terms of water volume (ml or cm ³ ).

Thus, the predicted value is calculated in volume of water (ml or cm ³ ). On the other hand, the amount of decrease in the water level, which is the measured value, is obtained based on the change in the height to the water surface, so its unit is (cm). Therefore, when comparing the predicted value and the measured value, the unit of one of them is aligned with the unit of the other.

In the first example, the measured value is the capacity (ml or cm ³ ) of the water storage tray 20 corresponding to the distance (cm) from the start point (water level at the start of measurement) to the end point (water level at the end of measurement). calculate. Then, it is compared with a predicted value (predicted decrease amount) obtained in units of ml or cm ³ .

In the second example, the predicted value obtained in volume (ml or cm ³ ) of the amount of water is converted to the amount of water level drop (cm) based on the dimensions of the water storage tray 20 . This is the predicted water level drop amount (cm). Then, the predicted water level drop amount (cm) is subtracted from the water level (starting point) (cm) at the start of measurement. As a result, a predicted value (cm) of the water level after a predetermined time is obtained. This predicted value of the water level is compared with the water level (end point) at the end of the actual measurement.

Using the predicted value of the amount of water level decrease per unit time determined as described above as the predetermined value when determining the presence or absence of dirt on the distance measuring sensor 24, for example, according to the flowchart shown in FIG. It is possible to determine whether or not the ranging sensor 24 is dirty.

[Third Embodiment]
Next, a third embodiment of the invention will be described. The air purifier 1 according to the third embodiment differs from the first embodiment in the method of determining whether the distance measuring sensor 24 is dirty. Other than that, the same configuration as in the first embodiment can be applied. Therefore, the points different from the first embodiment will be mainly described below.

In the third embodiment, the distance to the object to be measured is measured a plurality of times by the distance measuring sensor, the crosstalk component is removed from the detected distance component distribution, and the average value of the actual distance components is calculated as the distance L. A configuration example using a histogram type distance measuring sensor will be described.

In the air purifier 1 according to the present embodiment, when the distance to the water surface of the water storage tray 20 is measured multiple times using the histogram type distance measuring sensor 24, and the ratio of the effective distance data to the measurement data is 0.5 or less. Then, it is determined that the distance measuring sensor 24 is dirty.

FIG. 8 shows the water storage tray 20 and the distance measuring sensor 124 provided in the air purifier 1 according to the third embodiment.

A light emitting unit 151, a light receiving unit 152, and the like are provided on the lower surface of the distance measuring sensor 124. As shown in FIG. These configurations are similar to those of the first embodiment. Further, the distance measuring sensor 124 has a panel 124b having a light transmissive surface.

The distance measurement sensor 124 emits tens of thousands of lights from the light irradiation unit 151, and outputs the average value of the obtained measured distances as the measured distance. That is, the distance measurement sensor 124 performs measurements a plurality of times and determines the average value of the measured values as the measured distance. In this case, as shown in FIG. 8, measurements are made at two locations: a reflection component A (crosstalk component) from the panel 124b of the distance measuring sensor 124 and a reflection component B (actual distance component) from the water surface S to be actually measured. An average value of the distances will be calculated.

FIG. 9 shows a detection distance component distribution (histogram) obtained when the distance from the water storage tray 20 to the water surface S is measured using the distance measurement sensor 124 . This histogram is obtained when the lower surface of the distance measuring sensor 124 (in particular, the light irradiation section 151) is clean.

As shown in FIG. 9, the histogram includes peaks of the crosstalk component A distribution and peaks of the actual distance component B distribution.

Therefore, by removing the crosstalk component A from the obtained histogram and calculating the average value of only the actual distance component B as the distance L to the water surface, the water level of the water storage tray 20 can be measured more accurately. That is, the actual distance component B becomes effective distance data when the distance from the water storage tray 20 to the water surface S is measured.

When the lower surface of the distance measuring sensor 124 (in particular, the light irradiation section 151) is dirty, the ratio of the actual distance component B tends to be low in the obtained histogram. FIG. 10 shows a histogram when the distance to the water surface S is measured when the lower surface of the distance measuring sensor 124 (in particular, the light irradiation section 151) is considerably dirty. As compared with FIG. 9, it can be seen that the ratio of the crosstalk component A has increased and the ratio of the actual distance component B has decreased.

Therefore, in the present embodiment, when the control unit 41 calculates the distance L using the ranging sensor 124, in the acquired detection distance component distribution (histogram), the actual distance for (crosstalk component A + actual distance component B) A ratio of the distance component B (B/(A+B)) is also calculated.

Then, the control unit 41 executes different processing according to the calculated value of the actual distance component ratio (B/(A+B)).

Specifically, when the actual distance component ratio is greater than 0.5, it is determined that the distance measuring sensor 124 is clean and the measured distance L is accurate. Further, when the actual distance component ratio is 0.1 or more and 0.5 or less, it is determined that the distance measurement sensor 124 is dirty. Regarding the subsequent processing when it is determined that the distance measuring sensor 124 is dirty, the user may be notified by the same method as in the first embodiment.

Also, when the actual distance component ratio is less than 0.1, it is considered that the user is touching the lower surface of the distance measuring sensor 124 . Therefore, the control unit 41 determines that the user is cleaning the distance measuring sensor 124 .

(summary)
One aspect of the present invention relates to a humidifier (for example, humidified air cleaner 1). This humidifier includes a water storage container (for example, a water storage tray 20), a humidification mechanism (for example, a humidification filter 21) that releases water in the water storage container into the air, and a range sensor that detects the water level of the water storage container. (for example, the distance measuring sensor 24) and the amount of decrease in the water level of the water storage container per unit time determined from the water level detected by the distance measuring sensor is less than a predetermined value, the distance measuring sensor is abnormal. and a control unit (for example, control unit 41) that determines that

In the above humidifier according to one aspect of the present invention, the controller may determine whether or not there is an abnormality in the range sensor while the humidifier is in humidification operation.

In the above humidifier according to one aspect of the present invention, the predetermined value may be a predicted value of the amount of decrease in water level of the water storage container per unit time during the humidification operation.

Further, in the above humidifier according to one aspect of the present invention, the control unit controls the change per unit time of the water level detected by the range sensor (obtained in cm, for example) and the size of the water storage container. and the amount of water level drop per unit time in the reservoir (eg obtained in ml or cm ³ ) may be calculated. As a result, it is possible to easily and accurately compare with the predicted value of the amount of water level decrease per unit time obtained in units of ml or cm ³ .

In the above-described humidifier according to one aspect of the present invention, in a low temperature and high humidity state, the control unit determines whether or not there is an abnormality in the range sensor based on the amount of decrease in water level detected by the range sensor. may be omitted.

In the above humidifier according to one aspect of the present invention, the abnormality in the range sensor is, for example, contamination of the range sensor (for example, adhesion of scale). Abnormalities of the distance measuring sensor other than contamination include, for example, damage to the panel portion of the distance measuring sensor (for example, cracks, deformation, etc.), sticking of foreign matter (for example, insects, etc.), and the like.

Further, a humidifier according to another aspect of the present invention (for example, the humidified air cleaner 1 according to the third embodiment) includes a water storage container (for example, a water storage tray 20) and water in the water storage container. A humidification mechanism (e.g., humidification filter 21) that releases water into the inside, a distance sensor (e.g., distance measurement sensor 124) that detects the water level of the water storage container, and the distance measurement sensor measures the water level of the water storage container multiple times. and a control unit (for example, control unit 41) that determines that there is an abnormality in the distance measuring sensor when the ratio of the effective distance data to the measurement data is 0.5 or less. As with the humidifier according to one aspect of the present invention, the abnormality of the range sensor is, for example, contamination of the range sensor.

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the meaning and range of equivalents of the scope of the claims. Also, configurations obtained by combining configurations of different embodiments described herein are also included in the scope of the present invention.

1: Humidified air purifier (humidifier)
10: Housing 11: Blower 20: Water storage tray (water storage container)
21: Humidification filter (humidification mechanism)
24: distance measuring sensor 41: control section 124: distance measuring sensor

Claims (4)

a water reservoir;
a humidification mechanism for releasing water in the water storage container into the air;
a distance sensor that detects the water level of the water storage container;
a control unit that determines that the range sensor is abnormal when the amount of decrease in the water level of the water storage container per unit time determined from the water level detected by the range sensor is less than a predetermined value. a humidifier,
The control unit determines whether or not there is an abnormality in the range sensor while the humidifier is in humidification operation,
The humidifier, wherein the predetermined value is a predicted value of the amount of water level decrease per unit time in the water storage container during the humidification operation. The predicted value of the amount of water level decrease per unit time of the water storage container is calculated based on the indoor temperature and humidity during the humidification operation of the humidifier and the rotation speed of the blower provided in the humidifier. The humidifier according to claim 1, wherein 3. The humidifier according to claim 1 , wherein in a low temperature and high humidity state, said control unit does not determine whether said range sensor is abnormal based on the amount of water level drop detected by said range sensor . 4. The humidifier according to any one of claims 1 to 3, wherein the abnormality of the range finding sensor is contamination of the range finding sensor .

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